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UNIVERSITÀ DEGLI STUDI DI PADOVA
Dipartimento di Biologia
Centro di Ricerca Interdipartimentale per le Biotecnologie Innovative
- CRIBI -
SCUOLA DI DOTTORATO DI RICERCA IN BIOSCIENZE E BIOTECNOLOGIE
INDIRIZZO DI BIOTECNOLOGIE
XXVI CICLO
α -SYNUCLEIN OLIGOMERS INDUCED BY DOCOSAHEXAENOIC ACID
A STUDY OF ACTIVITY AND MOLECULAR CHARACTERIZATION
Direttore della scuola: Ch.mo Prof. Giuseppe ZANOTTI
Coordinatore di Indirizzo: Ch.ma Prof.ssa Fiorella LO SCHIAVO
Supervisore: Prof.ssa Patrizia POLVERINO DE LAURETO
Dottoranda: Chiara FECCHIO
A. A. 2013/2014
THESIS CONTENTS
Riassunto............................................................................................................................ 1
Summary............................................................................................................................ 5
1. Introduction....................................................................................................................8
1.1 Parkinson’s disease..........................................................................................8
1.1.1 Pathogenesis 5
Genetic factors in PD 6
Park1: aS gene 17
Post translational modification on aS 21
Oxidative stress 19
1.2 α-Synuclein.................................................................................................... 23
1.2.1. Primary structure 24
1.2.2. Secondary structure 26
1.2.3. Mutations on aS gene 29
1.2.4. Aggregation process 30
1.2.5 Factors that influence aggregation of aS 33
1.3 aS and lipids...................................................................................................36
1.3.1 Structural features 36
1.3.2 aS influence on lipid bilayers. 38
1.3.3 Lipids influence on aS properties. 39
1.3.4 Role of fatty acids 40
2. Matherial and methods................................................................................................. 43
2.1 Materials 43
2.2 Methods 43
2.2.1 Expression and purification of recombinant aS and aS mutants 43
2.2.2 Aggregation studies 43
2.2.3 Circular Dichroism 44
2.2.4 Gel filtration 44
2.2.5 RP-HPLC 44
2.2.6 SDS-PAGE 45
2.2.7 Native-PAGE 45
2.2.8 Liposome preparation 46
2.2.9 Thioflavin T binding assay (ThT) 46
2.2.10 Dynamic Light Scattering (DLS) 46
2.2.11 Transmission Electron Microscopy 46
2.2.12 Mass spectrometry 46
2.2.13 Proteolysis 47
2.2.14 Ion exchange chromatography 47
2.2.15 DNPH assay 47
2.2.16 Atomic Force Microscopy 48
2.2.17 Release assayes 48
2.2.18 Cell permeabilization assay 48
2.2.19 Planar Lipid membrane 49
3. Results aS/DHA OLIGOMERS CHARACTERIZATION.......................................................51
3.1 Aggregation process of aS in the presence of DHA and isolation
of oligomers 51
3.2 Chemico-physical characterization of aS/DHA oligomers 55
4. Results INTERACTION WITH MEMBRANES....................................................................59
4.1 Morphological analyses of liposomes 59
3.2 aS/DHA oligomers interact with membranes 60
3.3 Aggregation in the presence of lipids and membranes 62
3.4 aS/DHA oligomers induce permeabilization of synthetic membranes 65
4.5 aS/DHA oligomers permeabilize cellular membranes 67
4.6 Mechanism of permeabilization of aS/DHA oligomers of membranes 68
4.7 Pore formation 71
5. 5. CHEMICAL MODIFICATIONS ON aS/DHA OLIGOMERS..............................................79
5.1 DHA induces oxidative modifications on aS 79
5.2 Detection of DHA covalent adduct on aS 83
5.3 Role of His50 in oligomerization 86
6. aS FAMILIAR VARIANTS AND DHA.................................................................................95
6.1 Conformational analysis. 96
6.2 Proteolytic mapping of the complex protein/DHA. 98
6.3 Aggregation of as variants in the presence of DHA 102
7. Discussion.....................................................................................................................111
7.1 aS/DHA oligomers characterization 114
7.2 aS/DHA oligomers activity on membranes 116
7.3 Chemical modification of aS in the presence of DHA 118
7.4 aS variants in the presence of DHA 120
8. References....................................................................................................................123
Published paper (Fecchio et al., 2013)
List of figures
Figure 1.1 Loss of pigmented neurons in substantia nigra………………………………………........7
Figure 1.2 Fibril formation leads to neuron cell death........................................................8
Figure 1.3 Dopamine synthesis and pathway......................................................................9
Figure 1.4 Pathways in PD pathogenesis............................................................................11
Figure 1.5 Sequence of aS...................................................................................................14
Figure 1.6 Methionine and tyrosine oxidation scheme......................................................18
Figure 1.7 Schematic representation of aS structure......................................................... 24
Figure 1.8 Schematic representation of aS aggregation process........................................30
Figure 1.9 aS binding model to lipid vesicles......................................................………........37
Figure 1.10 Metabolism of polyunsaturated fatty acids…..................................................41
Figure 3.1 Gel filtration and RP-HPLC of aS/DHA mixture.………………………........................52
Figure 3.2 IEX chromatography of aS (A) and aS/DHA 1:50 ………………………………….……….........54
Figure 3.3 Far-UV CD spectra of monomeric and oligomeric aS..…………………………….........55
Figure 3.4 Structural characterization of aS/DHA oligomers …………….........…………….........57
Figure 4.1 DLS and TEM of SUV of different composition...................................................60
Figure 4.2 Far-UV CD of aS/DHA oligomers in the presence of vesicles...…….………….........61
Figure 4.3 Membrane damage caused by aggregation of aS on membrane......................62
Figure 4.4 Aggregation studies monitored by ThT assay …………………….………………………….63
Figure 4.5 Aggregation studies monitored by far-UV CD..……………..……….………..……….......64
Figure 4.6 Calcein-leakage test on liposomes ……….....................................……….……………66
Figure 4.7 PI influx in dopaminergic cells............................................................................67
Figure 4.8 DLS measurement of oligomers effect on liposomes.........……………………..........69
Figure 4.9 TEM of SUV in the absence and in the presence of aS/DHA oligomers.............70
Figure 4.10 Schematic representation of PLM........................................................................71
Figure 4.11 PLM experiments..................................................……………………….…..…..........71
Figure 5.1 Schematic representation of reaction of DNPH on carbonyls.……………………………….79
Figure 5.2 UV-Vis spectra of DNPH labeled aS....…………………………………………………………...81
Figure 5.3 RP-HPLC analyses of DNPH labeled aS.........................………..……………….……..…81
Figure 5.4 RP-HPLC analyses of proteolysis of DNPH labeled aS..............……………………….82
Figure 5.5 RP-HPLC analysis proteolysis of aS/DHA oligomers...........................................84
Figure 5.6 MS-MS of peptide 46-58…………………..........................................................……..85
Figure 5.7 Sequences of aS peptides with a Δ mass of 326 Da.….............…………..………..….85
Figure 5.8 Purification of H50Q.................................................…………………………………......86
Figure 5.9 CD spectra of aS and H50Q in the absence and in the presence of DHA...........87
Figure 5.10 RP-HPLC of aS and H50Q proteolysis in the presence of DHA......…….…………..87
Figure 5.11 Gel filtration of aS and H50Q aggregation.............….............…………..………..….88
Figure 5.12 RP-HPLC of aS and H50Q aggregation......................……………………………….......89
Figure 5.13 Mass spectrometry of H50Q/DHA oligomers...................................................90
Figure 5.14 H50Q/DHA oligomers proteolysis...............................................…………………..91
Figure 5.15 Calcein leakage test of aS and H50Q oligomers....….............…………..………..….91
Figure 6.1 Schematic representation of the localization of main aS mutations................……......95
Figure 6.2 Scheme of SL1 And SL2 binding model of aS to lipids........................................96
Figure 6.3 CD spectra of aS, A53T, E46K, A30P in the presence of DHA........…………………..97
Figure 6.4 Ellipticity at 208 nm of spectra in Fig. 6.3.….............……...............……..………..….98
Figure 6.5 RP-HPLC of proteolysis of E46K and A30P in the absence of DHA...………….......99
Figure 6.6 Limited proteolysis of aS, A30P, A53T and E46K in the presence of DHA........100
Figure 6.7 Extended proteolysis of A30P and E46K in the presence of DHA……...............101
Figure 6.8 Schematic representation of main cleavage sites on aS and aS variants.……..102
Figure 6.9 Gel filtration of aS, A30P, E46K and A53T ….................................……..………....103
Figure 6.10 TEM picture of oligomeric fractions of aS and aS variants...............…...….....104
Figure 6.11 CD spectra of aS and aS variants during aggregation.....................................105
Figure 6.12 RP-HPLC of aggregation of aS and aS variants...........................……...............106
Figure 7.1 Role of membrane in amyloid formation...........................................…...….....113
Figure 7.2 Schematic representation of Michael addition of 4-HNE on His50..........................119
Abbreviations
aS α-Synuclein
A30P aS variant, Ala30→Pro30
A53T aS variant, Ala53→Thr53
E46K aS variant, Glu46→Lys46
G51D aS variant, Gly51→Asp51
H50Q aS variant, His50→Gln50
AFM Atomic force microscopy
CD Circular dichroism
DHA Docosahexaenoic acid
DLS Dynamic light scattering
DLB Dementia with Lewy bodies
FA Fatty acids
FPLC Fast protein liquid chromatography
IEX Ions exchange chromatography
LBs Lewy bodies
LUV Large unilamellar vesicles
MS Mass spectrometry
MW Molecular weight
SDS Sodium dodecyl sulphate
PD Parkinson’s disease
PI Propidium Iodide
PLM Planar lipid membrane
PUFA Polyunsatured fatty acids
RP-HPLC Reverse phase high pressure liquid chromatography
SUV Small unilamellar vesicles
TEM Transmission electron microscopy
ThT Thioflavin T
Tris tris(hydroxymethyl)aminomethane
UV ultraviolet
Ala A Alanine Gly G Glycine Pro P Proline
Arg R Arginine His H Histidine Ser S Serine
Asn N Asparagine Ile I Isoleucine Thr T Threonine
Asp D Aspartic acid Leu L Leucine Trp W Tryptophan
Cys C Cysteine Lys K Lysine Tyr Y Tyrosine
Glu E Glutamic acid Met M Methionine Val V Valine
Gln Q Glutamine Phe F Phenylalanine
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RIASSUNTO
Il morbo di Parkinson (PD) è la principale malattia neurodegenerativa riguardante
la funzionalità motoria. L'1% della popolazione sopra i 65 anni è affetto da questa
malattia. I sintomi principali sono bradichinesia, tremore a riposo, instabilità posturale,
rigidità muscolare e, talvolta, problemi cognitivi e della personalità. Le principali
caratteristiche neuropatologiche del PD sono la morte dei neuroni dopaminergici a livello
della substantia nigra pars compacta e la formazione di corpi d’inclusione citoplasmatici
composti da aggregati proteici fibrillari di tipo amiloide, Lewy bodies (LBs), il cui
costituente principale è α-sinucleina (aS) (Spillantini et al., 1998). aS è proteina di 140
amminoacidi, natively unfolded, la cui funzione, nonostante il suo ruolo chiave nel PD,
non è ancora completamente chiarita. È espressa in livelli alti nel sistema nervoso
centrale ed è abbondante nei terminali presinaptici neuronali. Strutturalmente è
caratterizzata dalla presenza di sette ripetizioni imperfette di sequenza aminoacidica
(KTKEGV) nella regione N-terminale, da una regione idrofobica centrale (NAC, non-
amyloid component) e da una coda C-terminale con numerosi residui acidi. La
sovraespressione di aS e mutazioni nel suo gene sono associati a forme precoci della
sindrome di Parkinson. Il meccanismo con cui un cambiamento nella struttura e
nell’espressione della proteina possa portare allo sviluppo della malattia non è ancora
stato chiarito, ma è sempre più accreditata l’ipotesi che siano le forme oligomeriche e
non gli aggregati finali fibrillari ad essere responsabili della malattia.
Il progetto di questa Tesi riguarda la caratterizzazione di oligomeri tossici di α-
sinucleina (aS) ottenuti in presenza di acido docosaesaenoico (DHA) e lo studio della loro
interazione con membrane lipidiche, allo scopo di comprendere il meccanismo con cui
esercitano la loro tossicità. Il DHA è uno dei principali acido grassi cerebrali, strettamente
correlato al PD e ad aS. L’esposizione di colture cellulari dopaminergiche a PUFAs porta
all’accumulo di oligomeri solubili di aS, responsabili della citotossicità associata alla
neurodegenerazione (Assayag et al., 2007). Esistono poi evidenze dell’implicazione di aS
nella regolazione del metabolismo degli acidi grassi (Golovko et al., 2007). Inoltre è stato
osservato che, nei pazienti affetti da PD, la presenza di DHA è maggiore nelle aree
cerebrali contenenti inclusioni di aS. Studi in vivo, infine, hanno dimostrato che il DHA
induce la formazione di oligomeri di aS (Sharon et al., 2003). In precedenti studi condotti
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nel laboratorio dove è stata svolta questa Tesi è stato analizzato il processo di
aggregazione di aS in presenza di DHA, utilizzando due diversi rapporti molari
proteina/acido grasso) (De Franceschi et al., 2009) e gli aggregati proteici ottenuti in
queste condizioni sono stati caratterizzati da un punto di vista morfologico e strutturale
(De Franceschi et al., 2011). È stato osservato che la presenza di DHA in rapporto molare
50:1 rispetto alla proteina, porta alla formazione di oligomeri stabili, off-pathway nel
processo di fibrillazione, che presentano una significativa attività tossica sulle cellule
rispetto al monomero di aS.
Nella prima parte di questa ricerca è stata condotta una caratterizzazione di
queste specie oligomeriche che sono sufficientemente stabili nel tempo da consentire
l’uso di diverse tecniche biofisiche. In particolare gli oligomeri sono stati analizzati
mediante microscopia elettronica a trasmissione (TEM) e a forza atomica (AFM), per
studiare le dimensioni e la morfologia. Il tipo di struttura secondaria è stata valutata
mediante dicroismo circolare che ha dimostrato un’altra peculiarità di questi oligomeri,
ovvero la presenza di struttura parzialmente in α-elica, diversamente dalla maggior parte
degli oligomeri descritti in letteratura. È stata analizzata anche la capacità degli oligomeri
di interagire con le membrane, utilizzando liposomi di diversa dimensione e diversa
composizione e colture cellulari. L’interazione tra gli oligomeri e i liposomi, studiata
mediante CD e saggi di leakage, causa il rilascio di piccole molecole interne alle vescicole,
dimostrando così un loro effetto destabilizzante sulle membrane. L’attività degli oligomeri
è stata anche testata su cellule in coltura che mostrano un’alterata permeabilità in loro
presenza. Per determinare quale sia il meccanismo di destabilizzazione degli oligomeri,
sono stati eseguiti vari saggi. Si è dimostrato tramite dynamic light scattering (DLS) e TEM
che le vescicole, in seguito al legame con gli oligomeri, non vengono distrutte. Inoltre
mediante studi di aggregazione e analisi su planar lipid membrane portano a ipotizzare un
meccanismo di tossicità dovuto alla formazione di un’apertura transiente o un aumento
di flip-flop a livello delle membrane. I risultati di questa parte di tesi sono oggetto di una
pubblicazione (Fecchio et al., 2013).
Un altro aspetto che è stato approfondito in questo lavoro di Tesi è lo studio degli
oligomeri da un punto di vista chimico, allo scopo di caratterizzare le modifiche chimiche
presenti sulla sequenza della proteina in seguito all’esposizione al DHA. Sono state
evidenziate diverse modifiche mediante spettrometria di massa tra cui carbonilazioni e
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presenza di addotti. Quest’ultimo tipo di modifica in particolare avviene a livello
dell’istidina in posizione 50. Per approfondire il ruolo di questo aminoacido
nell’interazione con gli acidi grassi è stato studiato il mutante H50Q di aS. Questa
proteina modificata è tra l’altro responsabile di forme familiari del PD.
Infine è stata studiata anche l’interazione di altre varianti patologiche di aS associate
a PD, A30P, E46K e A53T con DHA. In particolare, è stata analizzata la loro struttura e la
loro tendenza ad aggregare in presenza di DHA, nonché la loro capacità di formare
oligomeri, in confronto ai risultati ottenuti con aS.
In conclusione questo studio ha permesso di fornire maggiori informazioni sulla
struttura e di studiare l’attività di specie oligomeriche che sono potenzialmente molto
rilevanti per la patogenesi del PD. La struttura e l’attività di questi oligomeri potrà essere
confrontata con quelle di oligomeri prodotti in diverse condizioni sperimentali o di
oligomeri prodotti da altre proteine amiloidogeniche. Questa conoscenza è fondamentale
per sviluppare agenti terapeutici che prevengano o debellino queste malattie debilitanti
ed in continuo aumento.
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SUMMARY
Parkinson disease (PD) is the main neurodegenerative disease that involves motor
symptoms. About 1% of population above 65 years is affected by PD. Main symptoms are
bradikinesia, resting tremor, postural instability, muscle rigidity, and sometimes, cognitive
problems and personality. Neuropathological features of PD are neuronal death in the
substantia nigra pars compacta and formation of cytoplasmatic inclusion, named Lewy
bodies, constituted by fibrillar form of α-synuclein (aS). aS is a 140 amino acid protein,
whose structure and function is yet not well defined. As a consequence of specific genetic
mutations or environmental factors, it undergoes aggregation and forms amyloid fibrils. It
is highly expressed in neuronal pre-synaptic nerve terminals. Its sequence is characterized
by an amphipathic lysine-rich amino terminus, which governs binding to lipids and
interactions with membranes and contains seven imperfect repetition of the sequence
KTKEGV; by a hydrophobic central region (NAC, non-amyloid component), responsible for
protein aggregation and β-sheet formation and a highly acidic C-terminal, rich in Pro and
acidic residues. Overexpression of aS and mutations in its gene are associated with a
premature development of PD. Mechanism that make aS a toxic protein has not yet been
well clarified, but it seems clear that oligomeric forms, and not the final fibrillar forms, are
the main responsible for the pathogenesis of PD.
The project of this thesis focuses on the characterization of oligomers of aS that
form in the presence of docosahexaenoic acid (DHA), and their interaction with
membrane, to understand the mechanism of toxicity. DHA is one of the most abundant
fatty acids in neuronal membrane and it has been correlated to PD. It has been
demonstrated that dopaminergic cell cultures exposed to PUFAs accumulate soluble
cytotoxic aS oligomers (Assayag et al., 2007). Indeed, aS seems to be involved in fatty
acids metabolism (Golovko et al., 2007). Moreover, it was reported that, in PD patients,
DHA concentration is enhanced in those area affected by aS inclusions. In vivo studies
demonstrated that a DHA enriched diet enhances formation of aS oligomers (Sharon et
al., 2003). In previous studies in this laboratory, it was analyzed the aggregation process
of aS in the presence of DHA using different protein to DHA molar ratios (De Franceschi et
al., 2009; 2011). Oligomers obtained in these conditions were characterized from a
morphological point of view (De Franceschi et al., 2011). The presence of DHA (50:1
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lipid:protein molar ratio) leads to the formation of stable oligomers, off-pathway in the
aggregation process of aS, that have significant toxic activity on cells, suggesting that they
are potentially relevant in the pathogenesis of PD (De Franceschi et al., 2011).
In the first part of this thesis a characterization of oligomers have been conducted
using several biophysical methods, since these oligomers are sufficiently stable to allow
the use of these techniques. In particular, transmission electron (TEM) and atomic force
(AFM) microscopy were used to study oligomers morphology and dimension. The
secondary structure was evaluated by circular dichroism (CD). This spectroscopic analysis
reveals that oligomers have a partial α-helix structure, in contrast with the majority of
oligomeric species described in literature. It was analyzed also the ability of oligomers to
interact with membrane, using liposomes of different size and composition and cell
cultures. Interaction of oligomers with membrane, analyzed by CD measurements and
leakage assays, causes the leakage of small molecule, demonstrating their ability to
destabilize membranes. Oligomers activity was tested also on dopaminergic cell culture
that showed an altered permeabilization after treatment. To determine the mechanism
by which oligomers cause membrane permeabilization, different tests were performed.
Initially, dynamic light scattering (DLS) and TEM allow to exclude a detergent-like effect.
Moreover, aggregation studies and planar lipid membrane (PLM) measurements lead to
hypothesize a toxicity mechanism that depends on the formation of a transient aperture
or on the enhancement of flip-flop. This part of the thesis is object of a publication
(Fecchio et al., 2013).
Another aspect faced in this thesis is the study of chemical modification occurring on
oligomers after exposition to DHA. Different chemical modification were evidenced by
mass spectrometry: carbonylation and the formation of adduct with DHA at the level of
His50. To deepen the role of this residue in the interaction with FA, it was used an aS
variant, H50Q, that has recently been linked to familiar form of PD.
Finally, also the interaction with DHA of other pathological variants of aS (A30P,
E46K, A53T) was studied. In particular their secondary structure and oligomerization in
the presence of DHA were analyzed, in comparison with results obtained with aS.
In conclusion, this study supplied further information about structure and activity
of oligomeric species that are potentially relevant in PD pathogenesis. These data can be
compared to oligomers produced in different conditions or formed by different
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amyloidogenic proteins: this knowledge would be fundamental to the development of
therapeutic agent that would prevent or defeat these kind of debilitative diseases.
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Fig. 1.1. substantia nigra: it is evident the loss of pigmented neurons in PD patients.
1. INTRODUCTION
1.1 Parkinson disease
Parkinson’s disease (PD), after Alzheimer’s disease, is the second most-prevalent
neurodegenerative disorder, affecting about 1 of peolpe over 60 (Van Den Eeden et al.,
2003). It was first described in 1817 by James Parkinson: it is an irreversible, progressive
disease that impairs movement causing tremors, bradykinesia, muscular rigidity and
postural instability, but the disease can be also associated to poorly treatable nonmotor
symptoms, such as depression, personality changes, dementia, sleep disturbances,
speech impairments (Lim and Lang, 2010). Aging is the only known definitive risk factor
for both idiopathic and sporadic PD (Tolleson and Fang, 2013): indeed, incidence
increases markedly with age. Young-onset Parkinson's disease, defined as occurrence
before age 40, accounts for just 5% of newly diagnosed cases (Irvine et al., 2008).
Moreover, upon reaching the 65-69 age range, 0.6% of the population is affected,
increasing to 2.6 % of those aged 85-89 (De Rijk et al., 2000). The majority of cases of PD
are believed to be idiopathic and sporadic, except for 5-10% of cases for which there is a
genetic component, showing both recessive and
dominant modes of inheritance. An other train of
thought support that environmental or genetic cause
for PD are a false dichotomy: many, if not all, cases of
PD contain contribution of both, albeit in varying
degrees (Singleton et al., 2013).
PD is caused by degeneration of dopaminergic (DA)
neurons that leads to depigmentation of the substantia
nigra pars compacta (SNpc) (Fig. 1.1). Pathologically,
PD is highlighted by the presence of eosinophillic,
intraneuronal proteinaceous inclusions known as Lewy
bodies (LBs) and dystrophic Lewy neurites in the
surviving neurons (Fig. 1.2 B, C). These intraneural
inclusions were described in 1912 by Friederick H. Lewy,
after investigation of histological features of sixty PD
patients’ brain (Lewy, 1912). LBs represent the cardinal
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hallmark of PD pathology, and have been considered to be a marker for neuronal
degeneration, because neuronal loss is found in the predilection sites for LBs
(Wakabayashi, 2007; Lees, 2009). However, it is not clear if the formation of LBs is a
primary mechanism or a consequence (Tolleson and Fang, 2013). Because patients
suffering from other neurological disorders can display parkinsonian features, a definitive
diagnosis of Parkinson’s disease can be confirmed only by post mortem histopathological
examination of the substantia nigra for the loss of pigmented neurons and presence of
LBs in remaining neurons. Identification of LBs has been facilitated by immunostaining for
particular proteins; initially for ubiquitin and more recently for aS, now regarded as the
major protein constituent (Shults, 2006). Such staining reveals filaments that, when
purified and examined by immuno-electron microscopy, can be seen to contain aS
(Spillantini et al., 1998). The recombinant protein forms similar filaments (Fig. 1.2 A) when
it is allowed to aggregate in vitro (Crowther et al., 1998).
Fig. 1.2. Schematic representation of neuronal loss in substantia nigra due to aS fibril formation, in brain of patience of PD. (reprinted from Ruipérez et al., 2010). Draw of LBs by Dr. Lewy (reprinted from Lewy 1923). (B) and (C) Nerve cell with three and two LBs that are double-stained for aS and ubiquitin. The halo of each LB is strongly immunoreactive for ubiquitin, whereas both the core and the halo of each Lewy body are immunoreactive for α-synuclein (Bar = 10 μm) (reprinted from Spillantini et al. 1998).
A
B C
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The motor complications caused by PD appear only after a significant loss of of dopamine
cells: approximately 50% in the SNpc and 80% in the striatum (Ozansoy and Basak, 2012).
The role of dopamine (DA) as neurotransmitter was defined in the late 1950s by the
Swedish scientist Arvid Carlsson, who deserved for this reason the Nobel Prize in 2000.
His studies were rapidly converted into clinical investigations and resulted within a few
years in the first clinical treatment of PD, a therapy that is still in wide use today
(Andersen, 2009). DA neurons operate in a pathway that controls voluntary movement.
This involves signals being relayed from the cerebral cortex through the basal ganglia back
to the cortex and then on to
muscles. Neurons from the
substantia nigra pars compacta
project axons that release
dopamine in synapses on
interneurons in the striatum.
As the dopamine containing
neurons die, failure to
complete this circuit results in
inability to coordinate
movement (Fig. 1.3).
Neuromelanin, the black
pigment that gives its name to
the substantia nigra (SN), is a
byproduct from the metabolic
pathway for dopamine
synthesis. When the
symptoms of PD first become
apparent, more than 70% of
the dopamine containing
neurons have already been
lost, releasing their
neuromelanin and hence
turning the tissue less black
Fig. 1.3. DA is synthesized in the cytoplasm by the action of tyrosine hydroxylase (TH) and amino acid decarboxylase (AADC). 1- As has been shown to regulate the activity of these enzymes. 2- Once synthesized, DA is immediately sequestered into vesicles by the vesicular monoamine transporter 2 (VMAT2). Several lines of evidence suggest that α-synuclein is involved in regulating synaptic vesicle function and dopamine release into the synaptic cleft. 3- Dopaminergic signaling at the synapse is terminated by the reuptake of dopamine via the dopamine transporter (DAT), with co-transport of two Na+ and one Cl− ions. Studies in cell culture systems have shown that α-synuclein is necessary for the trafficking of DAT to the cell surface (Reprinted from Venda et al., 2010).
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(Fig. 1.1). It is now apparent, however, that many regions of the brain are affected in
Parkinson’s disease, and indeed in the early stages it may affect only a lower region of the
brain stem called the medulla oblongata, spreading gradually upward through the basal
ganglia into the cortical areas (Irvine et al., 2008; Braak et al., 2003). Symptoms of PD
could be reversed temporarily by restoring striatal dopaminergic neurotransmission with
pharmacologic interventions (LeWitt, 2008; Hornykiewicz, 2002), using DA agonists,
compounds that directly stimulate postsynaptic receptors. The administration of
dopamine itself is ineffective because dopamine cannot cross the blood–brain barrier
(Nutt et al., 1984). Levodopa (3, 4-dihydroxy-L-phenylalanine), a naturally occurring
amino acid, is an intermediate in the pathway of dopamine synthesis (Fig. 3). After oral
ingestion, levodopa is actively transported from the upper small intestine into the
circulation by a mechanism specific for large, neutral L-amino acids. Because of ongoing
metabolism and the distribution of levodopa throughout the body, only a small fraction of
the drug reaches the brain after active transport across the blood–brain barrier. Once
there, dopamine is rapidly formed from levodopa by aromatic L-amino acid decarboxylase
(AAAD). Moreover, the coadministration of other drugs can improve the efficacy of
levodopa. In conclusion, current medications only provide symptomatic relief and fail to
halt the death of DA neurons. A major hurdle in development of neuroprotective
therapies are due to limited understanding of disease processes leading to death of DA
neurons (Thomas & Beal, 2007).
1.1.1 Pathogenesis
Although the majority of PD cases are idiopathic, about 10% of cases report with a
family history, and a growing number of mutations have been associated with familial and
sporadic forms of the disease (Lesage and Brice, 2009; Westerlund et al., 2010). The
primary pathological change in Parkinson's disease is the destruction of dopamine
containing cells in the zona compacta of substantia nigra (Jenner, 1989), so one important
question to study Parkinson’s disease is why dopaminergic neurons are particularly
vulnerable. One hypothesis is that the metabolic pathways for dopamine synthesis might
be at the root of the problem (Jenner, 1989). There is evidence that dopamine
metabolites can increase levels of reactive oxygen species that damage cells, especially
mitochondria; for example, neuromelanin binds heavy metals that can lead to free radical
- 11 -
production (Turnbullet al., 2001). The unique susceptibility of dopaminergic neurons to
some toxins, such as 1-methyl-4-phenyl-1, 2, 3, 6-tetrahydropyridine (MPTP) or
Rotenone, leads to another hypothesis that postulated exposure to environmental toxins
as the cause. For example, MPTP is taken up by the dopamine transporter, and this fact
explains the localization of pathological effects (Langston et al., 1983; Ramsay et al.,
1986; Dauer et al., 2003). However, while there are some cases where a single
environmental or monogenetic factor may lead to PD (MPTP poisoning or triplication of
aS, respectively) (Farrer et al., 2004, Przedborski et al., 2001 and Singleton et al., 2003), it
is more likely that a subtle yet complex interplay exists between genetic and
environmental factors in the etiology of disease. For example, the autosomal dominant
G2019S mutation in leucine-rich repeat kinase 2 (LRRK2) is the most common known
cause of familial and sporadic patients with PD, yet its penetrance is age-dependent, and
some individuals may never be afflicted (Goldwurm et al., 2007 and Kachergus et al.,
2005). The manifestation of such a predominant mutation as a late onset disorder, where
it is still not fully penetrant, suggests that genetic defects may serve to predispose
individuals to certain environmental challenges (Jason et al., 2011).
Fig. 1.4. Common pathways in PD pathogenesis that involve aS, with promoting (green arrows) or inhibitory (red lines) effects (reprinted from Thomas & Beal, 2007).
In Fig. 1.4 is reported a schematic representation of several different pathways
that are important in modulating pathogenic events. aS undergoes aggregation either due
to pathogenic mutations or catechol oxidation which in turn compromise UPS function,
- 12 -
induce endoplasmic reticulum stress and cause mitochondrial dysfunction. Mitochondrial
dysfunction and oxidative damage lead to deficits in ATP which may compromise US
function promoting abnormal protein aggregation. β-Synuclein is known to prevent aS
aggregation through activation of Akt signaling. Parkin, an ubiquitin E3 ligase,
promotesproteasomal degradation, increases mitochondrial biogenesis by activating
mitochondrial transcription factor A (TFAM) and block PINK1-induced mitochondrial
dysfunction, while pathogenic mutations, oxidative and nitrosative damage, severely
compromise its protective function. DJ-1 protects against oxidative stress, functions as a
chaperone to block aS aggregation and protects against mitochondrial dysfunction. PINK1
seems to protect against mitochondrial dysfunction which is compromised due to
pathogenic mutations, although the precise function of PINK1 in mitochondria still needs
to be determined. L-RRK2 seems to play a role in synaptic vesicle functions, neurite
outgrowth. Pathogenic mutations in LRRK2 cause abnormal protein phosphorylation
which induce mitochondria-dependent cell death. In addition, a pathogenic role of
PI3kinase-Akt (phosphatidylinositol 3-kinase/Akt) and Nrf2/ARE signaling is implicated in
PD pathogenesis. Familial PD-linked genes namely parkin, DJ-1 and PINK1 activate PI3
kinase-Akt signaling, while activation of Nrf2/ARE pathway prevents against oxidative
damage and mitochondrial dysfunction promoting cell survival (Thomas and Beal, 2007).
Genetic factors in PD
Ninety per cent of PD cases are sporadic. The remaining minority fraction of PD
patients carries genetic form of the disease: both autosomic dominant or autosomic
recessive gene mutations have been found. A distinction has to be done between two
terminologies. Parkinsonism defines the syndromic features of PD patients movement
disorders. It is consistent with the loss of dopaminergic neurons in SNpc and consequent
nigral degeneration. The second term is synucleinopathy that identifies all the pathologies
linked to aS accumulation in LB. This definition includes PD, dementia with Lewy bodies
and multiple system atrophy. All PD patients shows parkinsonism, but not all present aS
accumulation. Generally, these latter cases are directly correlated with autosomic
recessive PD. While autosomic dominant PD is linked to point mutant of aS A53T
(Polymeropoulos et al., 1997), A30P (Kruger et al., 1998) E46K (Zarranz et al., 2004), and
recently with H50Q (Proukakis et al., 2013) and G51D (Kiely et al., 2013) some recessive
- 13 -
genes are associated with mitochondria and oxidative-stress related survival pathways,
other with ubiquitin proteasomal system (Table 1.1).
Table 1.1. Summary of genetic locus and candidate genes for PD (Lai et al., 2012):
Locus Chromosome Gene Inheritance
PARK ¼ 4q21.3 SNCA Autosomal dominant
PARK 2 6q25.2-27 Parkin Autosomal recessive
PARK 3 2p13 Unknown Autosomal dominant
PARK 5 4p14 UCHL-1 Autosomal dominant
PARK 6 1p35-p36 PINK1 Autosomal recessive
PARK 7 1p36 DJ1 Autosomal recessive
PARK 8 12q12-q13.1 LRRK2 Autosomal dominant
PARK 9 1p36 ATP13A2 Autosomal recessive
PARK 10 1p32 Unknown Susceptibility locus
PARK 11 2q36-37 GIGYF2 Autosomal dominant
PARK 12 Xq21-25 Unknown X-linked
PARK 13 2p13.1 HTRA2/Omi Autosomal dominant
PARK 14 22q13.1 PLA2G6 Autosomal recessive
PARK 15 22q11.2-qter FBXO7 Autosomal recessive
PARK 16 1q32 Unknown Susceptibility locus
PARK 17 4p16 GAK Susceptibility locus
PARK 18 6p21.3 HLA-DRA Susceptibility locus
Till now, linkage studies have identified seventeen loci, named PARK, correlated
with PD or related disorders (Parkinsonism syndromes and LBD) (table 1.1, from Lai et al.,
2012). The loci include six autosomal dominant genes, the main are aS (SNCA) and
leucine-rich repeat kinase 2 (LRRK2), and six autosomal recessive genes, parkin, PTEN-
induced putative kinase 1 (PINK1), DJ-1, lysosome ATPase type (ATP13A2), PLA2G6, and
FBXO7. The ubiquitin carboxyl-terminal esterase L1 gene, (UCHL1, previously known as
PARK5), has only been found in one small family, and its importance in familial PD is still
uncertain. Identification of other Mendelian forms of PD still remains a main challenge in
PD research. PARK1 and PARK4 were initially assigned to different regions on
chromosome 4, but later ascribed to the same locus. Moreover, other genes, coming
from different loci, have been linked to PD and Parkinsonism, such as GBA
(glucocerebroside), MAPT (microtubule associated protein tau), spatacsin, ataxin 3 and
actasin 2 (Hardy, 2010). Unsurprisingly, the application of new techniques such as next
- 14 -
generation sequencing (NGS), genome-wide association studies (GWAS) and meta-
analyses have allowed for the discovery of new genes and genetic risk factors for
Parkinson disease and also other movement disorders, such as dystonia, essential tremor
and restless legs syndrome (RLS) (Kumar et al., 2012). As an example, two independent
studies utilized exome sequencing in a Swiss and an Austrian kindred to identify the same
p.D620N (c.1858G>A) mutation in the vacuolar protein sorting 5 homolog (VPS35) gene
as the cause of autosomal dominant Parkinson disease in these families (Vilarino-Guell et
al., 2011; Zimprich et al., 2011).
PARK1: aS gene
The discovery that aS is the main component of LBs is subsequent to the
recognition of a mutation linked to PD in the SNCA gene (Polymeropoulos et al., 1997).
Autosomal dominant early-onset PD has been linked to several point mutations (A30P,
A53T, E46K, H50Q and G51D) in the gene encoding aS (Polymeropoulos et al., 1997;
Kruger et al., 1998; Zarranz et al., 2004; Proukakis et al., 2013; Kiely et al., 2013. All
mutations are reported in Fig. 1.5.
1 10 20 30 40 50 60
MDVFMKGLSK AKEGVVAAAE KTKQGVAEAA GKTKEGVLYV GSKTKEGVVH GVATVAEKTK 70 80 90 100 110 120
EQVTNVGGAV VTGVTAVAQK TVEGAGSIAA ATGFVKKDQL GKNEEGAPQE GILEDMPVDP 130 140
DNEAYEMPSE EGYQDYEPEA Fig. 1.5. Sequence of aS. The point mutations linked to autosomal dominant early-onset PD are colored.
A53T was the first mutation to be identified: it causes earlier onset of the disease
(about 7-10 years earlier), and much lower prevalence of tremor compared with patients
with sporadic PD (Papapetropuolus et al., 2001). PD patients with A30P and E46K
mutation display as well earlier onset of the disease. Moreover, also duplications and
triplications of PARK1 locus cause autosomal dominant, early onset PD (Singleton et al.,
2003; Chartier-Harlin et al., 2004). The age of onset and severity of the disease phenotype
seems to correlate with SNCA copy number, suggesting a gene-dosage effect (Cookson,
2005). PD patients who carry duplications, which generate three copies of the gene, tend
to have PD which develops slowly from the 40s. Locus triplications, which produce four
- 15 -
copies of the SNCA gene, are responsible of earlier onset disease (mid 20-mid 30) (Farrer
et al., 2004; Wood-Kaczmar et al. 2006).
AS variants differ for the kinetics of fibrillation: the rate is increased for the A53T
and the E46K substitutions (Conway et al., 1998; Greenbaum et al., 2005), while it is
decreased in the case of A30P (Conway et al., 2000). Moreover, both the A53T and the
A30P mutations promote accumulation of prefibrillar oligomeric species (Conway et al.,
2000), while the E46K protein reduces the formation of such aggregates (Fredenburg et
al., 2007). Deep structural studies on the point-mutated aS variants have been performed
for the first mutants discovered, while poor data are available for the latest, i.e. H50Q and
G51D. NMR analyses have shown, for A30P, A53T and E46K, that these mutations have no
global effects on the structural properties of the protein or on the dynamic behaviour of
the aS backbone (Bussell & Eliezer, 2001, Fredenburg et al., 2007). Nevertheless, the
secondary structure propensity for the free disordered state of the wt protein is different
the three PD-linked variants. Specifically, the analysis of the Cα secondary shifts revealed
that the A30P mutation decrease the helical propensity found in the N-terminal region of
wt aS. The A53T mutation induces a more subtle and local preference for extended β-
sheet like conformations around the site of mutation (Bussell & Eliezer, 2001). The study
on E46K indicated that this mutation results in only very minor conformational changes in
the free state of aS (Fredenburg et al., 2007). Bertoncini et al. (2005b) analyzed the
perturbation induced by A30P and A53T mutantion in aS conformers ensemble. The two
variants show increased backbone flexibility and the absence of the long-range
interactions that were previously observed in the wt protein. In these mutants the
number of conformation available are larger and possibly there is a reduced shielding of
hydrophobic NAC. The possibility to an easier overcome of the energetic barrier for self-
association is reported as apossible cause for the increased propensity of these variants
to aggregate. Of interest, aS mutations have effect on the interactio of aS with lipids and
membranes: the A53T mutation seems to have little effect on membrane binding (Perrin
et al., 2000; Bussell & Eliezer, 2004). Instead, the A30P mutation decreases the extent of
lipid interactions in vitro and in vivo (Perrin et al., 2000; Jo et al., 2002; Jensen et al.,
1998), beacouse of the presence of a pro residue that act as a helical breaker. Specifically,
a N-terminal helix is interrupted at level of A27 to A37, leading to the formation of two
antiparallel helix (Ulmer and Bax, 2005). In contrast, E46K mutation increases the ability
- 16 -
of the protein to bind to negatively charged liposomes (Choi et al., 2004), since Lys
residue shift the net charge of the first 100 residues from +4 to +6 (Bodner et al., 2010).
Several different study have been conducted to study the consequence of aS variants
expression. Theei presence in cells seems to promote mitochondrial defects and cell
death and enhance susceptibility to oxidative stress. On the other hand, mice deficient in
aS are resistant to toxicity induced by MPTP and other mitochondrial toxins (Klivenyi et
al., 2006).
Post translational modification on aS
There are >300 different protein posttranslational modifications (PTMs), which
include such diverse processes as proteolysis, phosphorylation, lipidation, S-nitrosylation,
nitration, oxidation, glycosylation, methylation, adenosine diphosphate (ADP)-
ribosylation, acylation (acetylation, isoprenylation, myristoylation), ubiquitination,
sumoylation, sulfation, farnesylation, dityrosine crosslinking, methionine oxidation,
crosslinking by transglutaminase, truncation, and N-terminal acetylation and many others
(Aebersold et al., 2001). PTMs change the size, charge, structure and conformation of
proteins. As a result, characteristics of proteins, such as enzyme activity, binding affinity,
and protein hydrophobicity, are altered. PTMs cannot only directly change the proteins’
function but also indirectly affect function by leading to cell compartmentalization,
sequestration, degradation, elimination, and protein–protein interactions. Individual
proteins can undergo multiple and different PTMs (Aebersold et al., 2001). Protein
aggregation is a highly cooperative process, and even a small subpopulation of modified
aS could have a substantial impact on kinetics and product distribution. It has been
pointed out that only few post-translational modification have been described for aS. This
includes phosphorilation, methionine oxidation, dityrosine crosslinking, crosslinking by
transglutaminase, truncation, and N-terminal acetylation (Beyer, 2006). The known sites
of main PTMs in α-synuclein and their known effects on its conversion into disease-
related forms are discussed below.
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- Phosphorylation
In human α-synuclein in vivo, serine 129 was established as a major
phosphorylation site, with a second phosphorylation site located at serine 87. The major
phosphorylation site was found to be located within a consensus recognition sequence of
casein kinase 1 (CK-1). In vitro experiments and two-dimensional phosphopeptide
mapping provided further evidence that serine 129 was phosphorylated by CK-1 and CK-2,
both highly conserved sites (Okochi et al., 2000). About 90% of α-synuclein in LBs is
phosphorylated at Ser-129 (Fujiwara et al., 2002).
The effect of phosphorylation at Ser-129 on aggregation of α-synuclein has been
studied by expressing the S129A, to abolish phosphorylation at this site. Expression of
S129A alpha-synuclein instead of wild-type alpha-synuclein decreased the parkin-
mediated ubiquitination of synphilin-1 and the formation of ubiquitinated inclusions.
Moreover, treatment of SH-SY5Y cells with H2O2 increased alpha-synuclein
phosphorylation and enhanced the formation of inclusions, whereas treatment with the
casein kinase 2 inhibitor 5,6-dichloro-1-beta-d-ribofuranosylbenzimidazole had the
opposite affect. (Smith et al., 2005). This data shows that Ser-129 phosphorylation
promotes aggregation of α-synuclein. Phosphorylation at Ser-87, on the other hand,
expands the structure of α-synuclein, increases its conformational flexibility, and blocks
its aggregation in vitro. Furthermore, phosphorylation at S87, but not S129, results in
significant reduction of alpha-syn binding to membranes. (Paleologou et al., 2010)
- Oxidative modifications
The primary targets for oxidative modifications in α-synuclein are its methionine
and tyrosine residues. The α-synuclein primary sequence contains four tyrosine residues:
Tyr-39, Tyr-125, Tyr-133, and Tyr-136. These tyrosine residues are conserved in all α-
synuclein orthologs and in β-synuclein paralogs, suggesting that these residues might play
important functional roles (Dev et al., 2003). Studies have shown that exposure to
oxidative and nitrative species stabilizes alpha-synuclein filaments in vitro, and this
stabilization may be due to dityrosine cross-linking. (Norris et al., 2003). However, in a
cellular model of PD, only a significant increase in nitration of Tyr-39 was detected while
nitration levels of other tyrosine residues were unchanged (Danielson et al., 2009). The
difference could be due to a higher accessibility of Tyr-39 to a nitrating agent.
- 18 -
Methionine residues are also susceptible to oxidation to sulfoxide and ultimately sulfone
(Fig. 1.6). All four methionines in α-synuclein (Met-1, Met-5, Met-116, and Met-127)
located outside the repeat-containing region are highly susceptible to oxidation to
methionine sulfoxide MetO. Their oxidation inhibits fibrillation of this protein in vitro and
MetO protein also inhibits fibrillation of unmodified alpha-synuclein. Moreover, the
degree of inhibition of fibrillation by MetO alpha-synuclein is proportional to the number
of oxidized methionines (Hokenson et al., 2004).
Fig. 1.6. Methionine and tyrosine oxidation scheme. A — Tyr nitration, B — Tyr dimerization, and C — Met oxidation.
Since PD pathology is associated with dopaminergic neurons, the interaction
between aS and dopamine has been extensively investigated. Dopamine is known to bind
to α-synuclein non-covalently, inhibiting its fibrillation and stabilizing the oligomers
(Herrera et al., 2008). However, dopamine is highly susceptible to oxidation, and its
oxidation products can inhibit aS fibril formation, because DAQ might stabilize aS
protofibrils. These adducts drive aggregation of α-synuclein into aS/DAQ adducts that
retain an unfolded conformation. Only a small fraction of aS molecules interacts with DAQ
in a covalent way (Bisaglia et al., 2010).
- 19 -
Overall, oxidative modification can significantly alter the aggregation pathway of α-
synuclein, usually toward oligomer formation. The structure and toxicity of these
oligomers depend on the nature of modification and other experimental variables
(Breydo et al., 2012).
- Ubiquitination
Ubiquitin is a small protein that can be enzymatically attached to lysine residues of
various cellular proteins. Ubiquitination is used to target proteins for proteolytic
degradation. Although α-synuclein contains 15 lysine residues, Lys21, Lys23, Lys32, and
Lys34 are the major ubiquitination sites in vitro. Notably, filamentous alpha-synuclein is
less ubiquitinated than the soluble form and the major ubiquitination sites are localized
to Lys6, Lys10, and Lys12 at the amino-terminal region of filamentous alpha-synuclein in
vivo (Nonaka et al., 2005). Since ubiquitination is not required for the degradation of the
α-synuclein monomer, it appears that α-synuclein ubiquitination occurs after its
aggregation (Sampathu et al., 2003). The effect of monoubiquitination of aS on its
aggregation depends on the site of modification. However, monoubiquitination of aS by
SIAH ligase at multiple lysine residues promotes its aggregation in vitro and in vivo, which
is toxic to cells. Mass spectrometry analysis demonstrates that SIAH monoubiquitylates aS
at lysines 12, 21, and 23, which were previously shown to be ubiquitylated in Lewy
bodies. SIAH ubiquitylates lysines 10, 34, 43, and 96 as well (Rott et al., 2008).
- Modification by lipid-derived aldehydes
Highly reactive aldehydes (for example, 4-hydroxy-2-nonenal and
malondialdehyde) are produced by lipid peroxidation (H. Esterbauer, R.J. Schaur, H.
Zollner, Chemistry and biochemistry of 4-hydroxynonenal, malonaldehyde and related
aldehydes, Free Radic. Biol. Med.11 (1991) 81–128). aS has been shown to have affinity
for unsaturated fatty acids and membranes enriched in polyunsaturated fatty acids,
which are especially sensitive to oxidation under conditions of oxidative stress . One of
the most important products of lipid oxidation is 4-hydroxy-2-nonenal (HNE), which has
been implicated in the pathogenesis of Parkinson disease. Incubation of aS with HNE
resulted in covalent modification of the protein. HNE modification of alpha-synuclein led
to inhibition of fibrillation, due to the formation of stable oligomers toxic to cells.
- 20 -
Oligomers formed after reactions with 4-hydroxy-2-nonenal and 4-oxo-2-nonenal could
have different structures and morphologies. (Nasstrom et al., 2003; Qin et al., 2007;
Nasstrom et al., 2011). Overall, lysine modification of α-synuclein tends to promote the
formation of oligomers at the expense of fibrils. This is likely due to the ability of more
flexible structures of oligomers to accommodate these modifications. Similar behavior
has been observed for other amyloidogenic peptides and proteins (Bieschke et al., 2006).
Lipid induced modification of aS and relative pathological implications will be
further described in section 3.3.
Oxidative stress
Parkinson's disease (PD) is related to excess production of reactive oxygen species
(ROS) or inadequate and impaired detoxification by endogenous antioxidants, alterations
in catecholamine metabolism, alterations in mitochondrial electron transfer function, and
enhanced iron deposition in the substantia nigra (Reale et al., 2012). The formation of
reactive oxygen and nitrogen species damages also other cellular component such as
lipids, DNA and proteins. Oxidized proteins may not be adequately ubiquitinate or
recognized by the proteosome and may accumulate (Jenner, 2003). The concept that
oxidative stress is an important mechanism underlying the degeneration of dopaminergic
neurons is reinforced by data documenting that high levels of lipid peroxidation,
increased oxidation of proteins and DNA and depletion of glutathione are observed in
postmortem studies of brain tissues of PD patients (Reale et al., 2012). Lipid peroxidation
leads to the production of toxic species, such as 4-hydroxynonenal (HNE), detected by
immunocytochemistry in SN and cerebrospinal fluid of PD patients (Yoritaka et al., 1996).
HNE may act by covalently modifying proteins and impairing their function, disrupting
neuronal calcium homeostasis and perturbing mitochondrial function, through caspase
activation. Activated caspases, in turn, induce activation of JNK, resulting in stimulation of
AP-1 DNA-binding protein production. This transcriptional pathway induced by HNE may
modulate the cell death process. Moreover HNE has NF-kB inhibitor action that cause the
reduction of glutathione levels and the inhibition of complexes I and II of the
mitochondrial respiratory chain (Camandola et al., 2000; 2000b). Actually, plenty of
evidences underline the prominent role of oxidative stress as cellular damage mechanism
in PD. Synucleinopathies are usually associated with inflammation and elevated levels of
- 21 -
oxidative stress in affected brain areas, that could modify aS, especially when it binds to
biological membranes. The important aspect is that oxidative modifications can affect aS
aggregation. aS is such sensitive to oxidative stress because it could act physiologically as
a catalytically regenerated scavenger of oxidants in healthy cells (et al., 2013) with Cu, Zn-
SOD and H2O2, then the amount of oligomerization increased, especially for A53T mutant
form. This process was inhibited by radical scavenger and antioxidant molecules (Kang et
al., 2003). Another reported consequence of oxidative stress in dopaminergic neuron is
that of oxidation of Dopamine. It has been demonstrated that oxidation leads to the
formation of dopamine-derived orthoquinone (DAQ) that could react and bind to aS. This
modification seems to be inhibitory of the fibril formation process, causing accumulation
of aS protofibrils. Adduct formation provides an explanation for the dopaminergic
selectivity of α-synuclein–associated neurotoxicity in PD. Interestingly, these effects are
eliminated by antioxidants. Thus, three established risk factors—oxidative stress, DA, and
aS—may, in combination, stabilize protofibrillar aS and promote the pathogenesis of PD
(Conway et al., 2001). As a prerequisite, aS levels must exceed the critical concentration
for oligomerization. In rare familial forms of PD, that threshold may be lowered by aS
point mutations (Conway et al., 2000). Once the critical concentration of aS has been
exceeded, the cytoplasmic concentration of DAQ may be one of several factors that
determine the amount and lifetime of potentially pathogenic aS protofibrils (Conway et
al., 2001). DAQ results from a combination of oxidative stress and elevated cytoplasmic
DA concentration, both of which are independently associated with PD (Dunnett et al.,
1999).
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1.2 α-SYNUCLEIN
aS is a small (140 amino acids) cytoplasmic protein, expressed in all the central
nervous system, especially in the neocortex, hippocampus, striatum, thalamus, and
cerebellum (Iwai et al., 1995). It represents 0.5–1% of the total cytosolic protein in brain
(Kruger, 2000). It is highly expressed at the presynaptic level (Kahle et al., 2004), and
locally it is estimated to reach the concentration of 70-140 μM (van Raaij et al., 2008).
aS family is composed of four proteins: aS, β-synuclein (bS), μ-synuclein (mS) and
synoretin (synr) (Fig. 1.1). aS and bS have similar level of cellular expression and
distribution, while mS and synr are prevalently expressed in peripheral terminals. The
proteins in the family show a high degree of homology, however only aS is found in LB. bS
is not included in amyloidogenic fibrils because it does not contain aa 71-82 of aS,
believed to drive fibrillogenesis (Giasson et al., 2001). The function of these proteins is
still unknown. The location and some experimental data suggest an association with
presynaptic vesicles (Murphy et al., 2000). aS is proposed to regulate dopamine
neurotransmission by modulation of vesicular dopamine storage and catecholamine
release from the synaptic vesicles (Lotharius and Brundin, 2002). In particular, the
potential function of aS in DA regulation and storage is correlated with its ability to
interact with membranes and regulate vesicular trafficking (Lotharius and Brundin, 2002):
aS over-expression inhibits a vesicle ‘priming’ step that occurs after secretory vesicle
trafficking to ‘docking’ sites but before calcium-dependent vesicle membrane fusion
(Larsen et al., 2006). In addition, aS seems to be involved in synaptic plasticity and
learning (Clayton & George, 1998), indeed it is upregulated in songbirds, during the
periods of song-learning, this is a function related with synaptic plasticity (George et al.,
1995). Interestingly, knockout mice for aS are quite normal, showing only an increase of
dopamine release in response to electrical stimuli (Abeliovich et al., 2000). Genome wide
screening in yeast showed that nearly one-third of genes that enhance the toxicity of aS
are functionally related to lipid metabolism and vesicle trafficking (Willingham et al.,
2003). An analysis of a yeast PD model with dosage sensitivity for aS expression (Outeiro
& Lindquist, 2003) revealed that the earliest defects following aS expression were an
inhibition of the endoplasmic reticulum to Golgi vesicular trafficking and an impairment
- 23 -
of the endoplasmic reticulum associated degradation (Cooper et al., 2006). Finally, it was
revealed that aS regulates.
Another possible hypothesis, on the base of its abundance in the cytosol, its
unfolded structure, and its prevention of protein aggregation induced by heat shock or
chemical treatment, concerns a putative role of aS as chaperone (Souza et al., 2000).
Actually, aS can act as a molecular chaperone assisting in the folding and refolding of
synaptic proteins called soluble NSF (N-ethylmaleimide sensitive factor) attachment
receptors (Chandra et al., 2005). A recent proteomic study evidenced 587 proteins as aS-
binding partners in a neuronal-hybrid cell line (Jin et al, 2007). Even considering the
possibility of an overestimation, the chaperone activity could well fit with the huge
number of protein-interactions. aS overexpression rescues lethality associated with the
lack of CSPα, a co-chaperone (HSP40 kind) associated with synaptic vesicles and
implicated in folding of SNARE proteins, confirming that aS may act as an auxiliary
chaperone preserving the function and integrity of the synapse (Chandra et al., 2005).
1.2.1 Primary structure
aS is a 140 amino acid protein with four tyrosine residues, four methionine
residues and one residue of histidine, deprived of cysteine as well as tryptophan residues.
The primary sequence divides the protein in three regions: the N-terminal region (amino
acid 1–60), the central region (61–95) and the C-terminal region (96–140) (Fig. 1.7). The
N-terminal region, residues 1–60, includes the sites of three familial PD mutations and
contains six imperfect repeats of the motif KTKEGV that is involved in the binding of
detergents micelles and liposomes. This region adopts an amphipathic α-helix structure
when the protein binds to phospholipids (Davidson et al., 1998), that it is comparable to
A2 helix type of apolipoproteins (Clayton &George, 1998). At the interface between the
hydrophobic half and the hydrophilic one lysine residues are present to mediate the
interaction, as the amine is positively charged and the aliphatic chain can interact with
lipids. This is why aS prefers negatively charged vesicle to interact with. The central
region, residues 61–95, comprises the highly aggregation-prone NAC sequence (Ueda et
al., 1993; Han et al., 1995) and contains the remaining three imperfect repeats. NAC is the
acronym of Non β- Amyloid Component, as this part of the molecule is also found in
- 24 -
amyloid plaques of Alzheimer’s disease patients brains (Ueda et al., 1993; Weinreb et al.
1996, Goedert, 1997; Jo et al. 2000).
Fig. 1.7. Schematic representation of aS structure. Most important characteristics about aggregation (blue), KTKEGV repeats (light-blue), acidic residues (black), mutations (red) and phosphorilation sites (green) are reported.
This region is highly hydrophobic, and it can acquire β-sheet structure as it is the leader of
amyloid fibril formation. In particular, aa 71-82 was described to be the responsible
(Giasson et al., 2001) of aS aggregation, as deletion mutants do not form β-sheet
structured fibrils, neither do bS, which lacks this region.
The C-terminal region is an acidic segment rich in glutamic, aspartic and proline residues.
This region determines the acidic isoelectric point of the α-syn (pI = 4.7) (Hoyer et al.,
2002). The C-terminal region, residues 96–140, is highly dynamic in most conditions: it
does not acquire structure in any condition. A regular repetition of the acidic residues can
be observed: The region has a mM affinity for the binding of metals like Ca2+, Fe2+/3+, Al3+,
Co2+ and Mn2+ (Uversky et al., 2001). Divalent metal binding has been shown to increase
fibril formation rate. Ser129 is site of phosphorylation (Takahashi et al., 2003) and
phosphorylated aS forms fibrils slower than wild type protein (Paleologou et al., 2008);
phosphorylated aS is also found in PD patients LB (Takahashi et al., 2003). Also C-terminal
tail seems to be involved in intermolecular interaction with the N-terminal part of the
region, just for electrostatic interactions. Observing the primary sequence, it becomes
evident that all the missense mutations diseases-associated, reside in the N-terminal
region.
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1.2.2 Secondary structure of aS
Since the discovery of aS amyloid fibrils as main component of LBs inclusions, the
protein has been deeply examined in a massive number of structural studies. aS has been
cloned and produced in bacteria for the first time in 1994 (Jakes et al., 1994), and
recombinant aS was shown to be able to form amyloid fibrils in vitro (Conway et al.,
1998). Until recently, aS was valued as a heat-stable protein, with a monomeric natively
unfolded structure (Weinreb et al., 1996). In vitro studies on recombinant aS show that
the aS monomer lacks of ordered secondary structure under physiological conditions,
detectable by far-UV circular dichroism (CD), Fourier transform IR (FT-IR) and NMR
spectroscopy. For this reason, aS is considered a typical intrinsically disordered (or
natively unfolded) protein, which possesses little or no ordered structure under
physiological conditions in vitro (Uversky et al., 2001). Intrinsically disordered proteins
have been recognized as a protein class, which are gaining considerable attention due to
their capability to perform numerous biological functions despite the lack of unique
structure (Wright and Dyson 1999; Uversky et al. 2000, 2005, 2007). These proteins exist
as dynamic and highly flexible ensembles that undergo a number of distinct
interconversions on different time scales. In general, one of the main physical
characteristic of this set of protein is the combination of low overall hydrophobicity and
large net charge. However, aS does not fit this general trend. In its case, N- and C-terminal
regions possess charge of opposite sign and are separated by an extended hydrophobic
region (Uversky et al., 2000). Indeed, this monomer could assume different
conformational structures that hinder the amyloidogenic region. There are long-range
interactions between both the N- and C-terminal with the non-amyloid component region
(NAC). In particular, a long-range intramolecular interaction between the C-terminal
region (residues 120–140) and the central part of aS (residues 30–100) was noted
(Bertoncini, et al., 2005; Dedmon et al., 2005). These interactions avoid NAC–NAC contact
between different monomers, which is the basis for the oligomerization and aggregation
of α-syn. This is an intrinsic autoinhibitory mechanism that should be disrupted in order
to favor aS oligomers and fibrils formation (Bertoncini, et al., 2005; Bernardo et al., 2005).
Small angle X-ray scattering analysis showed that the radius of gyration, Rg, which is used
to describe the dimensions of polypeptide chain, is ~ 40 Å of native aS, which is much
larger than that predicted for a folded globular protein of 140 residues (15 Å), but
- 26 -
significantly smaller than that for a fully unfolded random coil (52 Å). Paramagnetic
relaxation enhancement (PRE) NMR spectroscopy (Dedmon et al., 2005; Bertoncini et al.,
2005) and fluorescence based studies (Lee et al., 2004; 2005) gave a molecular
characterization of this partial condensation suggested the presence of the numerous
long-range interactions, forming a hydrophobic cluster that comprised the C-terminal part
of the highly hydrophobic NAC region (residues 85–95) and the C terminus (residues 110–
130), probably mediated by M116, V118, Y125, and M127. Region 110-130 in the
negatively charged C-terminal tail can contact residues 85-95 in the centre of the protein.
Within the C-terminal region, residues 120-130 can contact residues 105-115, and the
region about residues 120 also can interact with the N-terminus about residues 20
(Bertoncini et al., 2005). The forces involved singnificantly decrease in high salt
concentration (Hoyer et al., 2004). These long-range interactions was suggested to inhibit
the spontaneous aS oligomerization and aggregation. The autoinhibitory conformations
fluctuate in the range of nanoseconds to micro-seconds, corresponding to the time scale
of secondary structure formation during folding. This highly dynamic tertiary structure
could explain the influece of such conditions that favour aS aggregation, as for example
temperaure increase (Bertonici et al., 2005). Indeed, this kind of interaction are important
for the shielding of NAC region, which has been proposed to lead protein aggregation. So,
all the conditions that favour the shielding action of the C-terminal tail result in a faster
protein aggregation. The conformational behavior of aS under a variety of conditions was
extensively analyzed (Uversky, 2003). The structure of aS is extremely sensitive to its
environment and can be easily modulated by a change in conditions. Beside an extended
state, aS can acquire a pre-molten globule state in several conditions such as low pH, high
temperature, in the presence of various metal ions and as a result of spontaneous
oligomerization both in vitro and in vivo (Uversky, et al., 2001; Uversky, 2007). Moreover,
in vitro studies demonstrate that recombinant aS can assume various -helical structures
interacting with lipid vesicles (Davidson et al., 1998). Eliezer et al. (2001) documented the
tendency of the first 100 residues of aS towards α-helical torsion angles, and the
following paper of the same group quantified this trend to exists for the about the 10% of
the time (Bussell & Eliezer, 2001). Kim et al. (2007) found that region comprehending aa
39–98 of aS polypeptide chain is able to populate β-sheet conformations in solution at
supercooling temperatures. This finding is relevant for the understanding of the first steps
- 27 -
leading to amyloid fibril formation by aS. In addition, other works confirmed that aS is
present in solution as an ensemble of conformers able to interchange each other in the
microsecond timescale (Maiti et al., 2004; Lee et al., 2004; 2005). aS can also move from a
fibrillation prone partially folded conformation to β-sheet species both in monomeric and
oligomeric states. Its aggregates can be morphologically different, including spheres or
ring oligomers, insoluble amorphous aggregates and amyloid fibrils (Uversky, 2003;
Uversky, 2007). Based on this conformational behaviour, Uversky proposed the concept
of chameleon protein, which holds that the structure of aS is modulated by its
environment to a dramatic degree. That is, the choice among all the above mentioned
conformations is determined by the peculiarities of protein surroundings (Uversky, 2003;
Uversky et al., 2007). Because of its plasticity, aS chameleon protein could be able to
perform multiple functions. Indeed, Wright and Dyson proposed a reassessing of the
structure-function paradigm due to the peculiarities of natively unfolded proteins (Wright
and Dyson, 1999).
Data summarized so far refers to structural in vitro studies on recombinant aS.
Some drawbacks of using recombinant are forcing non-physiological conditions, depriving
the protein of the physiological modification it could be affected and of physiological
binding partners and local ion environment. The native-unfolded paradigm was disputed
by the work of Selkoe’s laboratory, which showed that aS in its native state is a folded
tetramer, rich in α-helix, with greater lipid-binding affinity than the monomer and
resistant to fibril formation. In addition this tetrameric aS is N-acetylated in vivo, at least
in human erythrocytes where most of the characterization was done (Bartels, J.G. Choi,
D.J. Selkoe, Nature 477 (2011) 107–110]. Tetrameric state was hypothesized on the base
of native gels results (about 48 kDa) and scanning transmission electron microscopy
(STEM) measurements (55 kDa average). STEM imaging yielded a homogenous
distribution of roughly spherical particles measuring about 3-3.5 nm in diameter, and CD
measurement demonstrate that this particles have α-helical structure. Purified tetramers
show higher affinity for negatively charged lipids than recombinant aS, and, most of all,
less ability to aggregate. Soon, this work was challenged and laboratories from different
places concluded that aS is a native monomeric and unstructured protein in erythrocytes
and in the nervous system (Fauvet et al., 2012). These findings are in disagreement with
most of published results obtained studying recombinant aS, and, if confirmed, would
- 28 -
lead to several functional implications on aS physiological role. Authors explain the
divergence with the use of denaturing agents, including sample heating, during the
standard purification of recombinant aS from bacteria (Bartels et al., 2011). A second
study published by Wang and colleagues sustains the thesis of α-helical folded tetramer
as native state of aS, that can be present in physiological conditions, while the unfolded
structure can be a precursor of the aggregation-prone conformation.
1.2.3 Mutations on aS gene
The first missense mutation found in aS was A53T, followed by two additional
disease-causing missense mutations: A30P mutation in a German family (Kruger et al.,
1998), and an E46K mutation in a Spanish family (Zarranz et al., 2004). In vitro, aS can
readily form fibrils similar to those seen in LBs (Conway et al., 1998, Giasson et al.,
1999 and Wood et al., 1999) and the mutations can influence the kinetics of aS
fibrillation: E46K and A53T can both increase rate of fibril formation, while A30P
decreases it (Conway et al., 1998 and 2000, Giasson et al., 1999 and Greenbaum et al.,
2005). Focusing on oligomeric species, A30P and A53T show a higher accumulation of pre-
fibrillar species, while E46K reduces them (Conway et al., 2000; Fredenburg et al., 2007).
Interestingly, A53T and A30P mutants are able to form prefibrillar intermediates with
pore-like activity, providing explanation for their toxicity (Conway et al., 2001; Volles &
Lansbury, 2002). AS mutants were analyzed for their secondary structure futures,
resulting different from aS WT. Specifically, the analysis of A30P reveals that it has a
minor helical propensity compared to that found in the N-terminal region of wt aS,
whereas the A53T mutation induce a more subtle and local preference for extended β-
sheet like conformations around the site of mutation (Bussell & Eliezer, 2001). These two
variants show increased backbone flexibility, while E46K do not. The important long-
range interactions that prevent aSWT to assume an aggreation-prone confomration, are
absent, so In these mutants the number of conformation available are larger and this
could lead to a reduced shielding of hydrophobic NAC. The possibility to an easier
overcome of the energetic barrier for self-association has been suggested by the authors
as the cause for the increased propensity of these proteins to aggregate (Bertoncini et al.,
2005b).
- 29 -
Recently, a new missense mutation have been reported: H50Q (Proukakis et al.,
2013; Appel-Cresswell et al., 2013). H50Q’s characteristics are still under study, but
authors assert that their protein modeling provide additional support for pathogenicity as
the amino acid perturbs the same amphipathic alpha helical structure as the previously
described pathogenic mutations. The mutation of H50Q was found to significantly
accelerate the aggregation and amyloid formation of aS in vitro. This mutation, however,
did not alter the overall secondary structure as suggested by two-dimensional nuclear
magnetic resonance and circular dichroism spectroscopy. The initial oligomerization study
by cross-linking and chromatographic techniques suggested that this mutant oligomerizes
to an extent similar to that of the wild-type (Ghosh et al., 2013). Link between aS
aggregation and PD was further strengthened with the identification of several PD
kindreds with triplication (Farrer et al., 2004 and Singleton et al., 2003) or duplication of
the aS gene (Chartier-Harlin et al., 2004). In vitro, increased concentrations of aS have
been shown to promote the polymerization into fibrils (Wood et al., 1999), and patients
with a gene triplication have greater disease severity and younger age of onset than those
with gene duplication, suggesting a possible “SNCA gene dosage effect” leading to PD
(Singleton and Gwinn-Hardy, 2004). Furthermore, these findings indicate that a 50%
increase in the expression of aS due to gene duplication is sufficient to cause disease and
is consistent with the aggregation of α-synuclein contributing to disease (Jason et
al.,2011).
1.2.4 Aggregation process
Some pathologies, as for example Alzheimer disease, PD and Prion diseases are
associated with the formation of protein aggregates that form large deposits (Koo et al.,
1999; Serpell, 2000). Each amyloid disease involves predominantly the aggregation of a
specific protein, although a range of other components including are incorporated into
the deposits in vivo. The aggregation process of aS was extensively studied as aS amyloid
fibrils were observed in LBs (Fig. 1.1).
- 30 -
Fig. 1.8. Conformational states of a protein in a cell and subsequent destinies (From Dobson, 2003). The unfolded polypeptide chain can assume 3D structure after translation or it can be degraded or form amorphous aggregates. Intermediates can be assemble into prefibrillar species that lead to amyloid fibril formation.
Those macromolecular structures were reproduced in vitro, to be studied in order
to identify their 3D structure. The in vitro kinetics of aS fibril formation show an initial lag-
phase followed by an exponential growth phase and a final plateau, usually attributed to
a nucleation-dependent polymerization. aS fibrils obtained in vitro, are formed by two or
more filaments (Fig. 1.8). They typically vary in length from about 500 nm to 3 μm and,
based on AFM analyses, have an average height of 9.8 ±1.2 nm (Fink, 2006; Khurana et al.,
2003). The core region of aS, defined by proteolysis studies, encompass the central, highly
amyloidogenic NAC region (Miake et al., 2002; Quin et al. 2007). EPR and site-directed
spin labelling studies indicate that the fibril core is formed by parallel, in-register
arrangement of multiple β-strands that run perpendicular to the fibril axis, where each
layer contain a new molecules (Chen et al., 2003). The fibril core is actually supposed to
be constituted by five β-strands, as revealed by D/H exchange experiments (Vilar et al.,
2008; Karyagina et al., 2011).
- 31 -
Even though the ability to form amyloid fibrils seems to be generic (Dobson,
2001), the propensity to do so under given circumstances can vary markedly between
different sequences. The relative aggregation rates for a wide range of peptides and
proteins correlates with the physicochemical features of the molecules such as charge,
secondary-structure propensities and hydrophobicity (Chiti et al., 2003). As already said,
the in vitro kinetics of aS fibril formation show an initial lag-phase followed by an
exponential growth phase and a final plateau (Fink, 2006). The lag-phase is due to the fact
that the process is nucleation-dependent, meaning that the rate limiting step is the
formation of a nucleus composed of a critical numbers of monomers (Wood et al., 1999;
Murphy, 2007). The constitution of the nucleus is hosted, as monomers has to be in those
rare and limited conformations prone to a stable interaction once contact has occurred
each other. However, once this passage has been achieved, elongation or enlargement is
a thermodynamically favoured process. Uversky and coworkers showed that early stages
of fibril formation involve the partial folding of aS into the highly fibrillation-prone pre-
molten globule-like conformation, which represents a key intermediate on the fibrillation
pathway (Uversky et al. 2001, Fink, 2006). Hence, factors that shift the equilibrium in
favor of this partially folded conformation facilitate fibril formation. Thus, an increase in
protein concentration is predicted to increase the concentration of the intermediate, and
so the rate of fibrillation (Uversky et al., 2001). Since, as previuosly reported, the
unstructured monomer presents long-range interactions between the C-terminal and the
central NAC regions (Bertoncini et al., 2005), an event that leads to the formation of an
unfolded state should be expected prior to the aggregation. Moreover, it has been
recently suggested that aS could be folded as an α-helical tetramer (Bartel et al., 2011;
Wang et al., 2011). The aggregation-prone conformation may be attained early in the
aggregation pathway, through the exposition of the hydrophobic NAC region and
facilitating aggregation (Paleček et al., 2008). To favor the aggregation prone
conformation, structural perturbations are necessary. They could be caused by different
conditions, including for example the presence of positively charged ions able to interact
with the C terminus, a decrease in pH that reduce the net charge of the C-terminal region,
and the deletion of the C terminus, result in a more rapid aggregation reaction (Hoyer et
al., 2004). Even when the partially unfolded states is reached, the probability of
interaction of two of pre-molten globule species is low, but it may occur the case in which
- 32 -
stable hydrogen bonds formation is established. Later, dimers can form stable contacts
with other units, and oligomers start to grow. Soluble oligomers convert to fibrillation
intermediates, designated protofibrils (Harper et al., 1997). Analysis by TEM and AFM has
revealed that different final product may arise from the aggregation of aS depending on
the experimental conditions: fibrils, oligomers, and insoluble amorphous aggregates (Fink,
2006). Although the central role of aS fibrillation in the pathogenesis of PD is well
established, it has been demostrated that aS fibrils may not be the toxic species, but may
also have a protective role. On the contrary, soluble oligomers and protofibrils seem to be
the toxic species (Volles et al., 2002). The oligomeric species of aS present during the lag-
phase of the aggregation process are relatively unstable, transient and present at very
low steady-state concentrations (Goldberg et al., 2000). As a result of the unstable and
transient nature of these intermediates, the direct detection and characterization of
prefibrillar oligomeric species oculd be extremely difficult. Several oligomeric prefibrillar
species with various morphologies have been described (Conway et al. 1998, 2000; Ding
et al. 2002; Lashuel et al. 2002, Apetri et al. 2006). These species are usually
characterized by extensive β-structure and sufficient structural regularity to bind
Thioflavin-T (ThT) and Congo Red (CR) (Chiti & Dobson, 2006). However, some types of
oligomers are unable to bind Thioflavin T ThT and CR (Apetri et al., 2006). Indeed several
oligomeric species have been identified by different techniques: photo-induced cross-
linking of aS (Li et al., 2006); electrochemical techniques (Paleček et al., 2007); intrinsic
tryptophan fluorescence of Y39W aS (Dusa et al., 2006) and FRET measurements (Kaylor
et al., 2005); fluorescence of pyrene-labeled aS (Thirunavukkuarasu et al., 2008).
Structured protofibrillar species could form from the reorganization or assembly of small
and relatively disorganized oligomers that are formed rapidly after the initiation of
aggregation process. In Fig. 1.8 a schematic representation of the hypothetical
aggregation pathways of aS is reported. Moreover, also stable oligomers with very slow
rates of dissociation, have been decribed. These oligomers could arise as a consequence
of different mofications, sucha as oxidation of the four methionine residues to
methionine sulfoxide (Hokenson et al., 2004), specific nitration of the tyrosine residues
(Uversky et al., 2005) and covalent modification by 4-hydroxynonenal (Qin et al., 2006).
Typically these oligomers are formed more rapidly than fibrils and, as a consequence, no
significant fibrillation occurs from these modified forms of aS.
- 33 -
1.2.5 Factors that influence aS aggregation process
Even if the comprehension of the aggregation and fibril formation processes is
incomplete, several factors have been reported to have an influence on the aggregation
pathway and kinetic, with inhibiting or promoting effects. As previously said, aS
undergoes a nucleation dependent mechanism of aggregation, so that every factor that
can increase the probability of the acquisition of an aggregation-prone conformation,
enhance fibrillogenesis. For example, a promoting factor could be the increase in
temperature, that is directly correlated with kinetic energy of molecules and also to
enhanced reactivity of species. Also a high protein concentration could increases the
probability of oligomers formation because conformers able to form the critical nucleus
are more concentrated, and this explain the effect of a familiar form of PD due to the
triplication of aS, that leads to autosomal dominant PD (Singleton et al., 2004). As a
consequence of the partial stability due to the interaction between different regions of
aS, proteolytic cleavage of aS, revealed to occur naturally in neuronal cell (Li et al., 2005),
increases fibrillogenesis. Specifically, by in vitro studies, C-terminal truncation has been
reported to enhance fibril formation of aS by exposition of hydrophobic NAC region
(Crowther et al., 1998; Hoyer et al., 2004). Also ionic strength enhances fibrillogenesis,
since it masks C-terminal negative charges, disrupting tertiary contacts between N-
terminal and the C-terminal of the protein, thus leading to exposition of hydrophobic
patches (Hoyer et al., 2004). Other mechanisms that involve charge and so the tertiary
contacts, is pH. The isoelectric point of aS is 4.6: so more acidic pH leads to disruption of
contacts between C-terminal tail and positive charges N-terminal region (Uversky et al.,
2001b). Among molecules that enhance aggregation propensity of aS, there are lipids,
expecially in the case of polyunsaturated fatty acids like arachidonic acid and
docosohexaenoic acid (Perrin et al., 2001). High protein:lipid molar ratio increases fibril
formation probabilities (Zhu et al., 2003): lipid membranes could recruite aS molecules
and, enhancing local protein concentration, favor protein-protein interaction. Other
involved molecules could be proteins that have been identified to stimulate aS in vitro
aggregation at substoichometric concentrations, like tau (Norris & Giasson, 2005),
histones (Goers et al., 2003), brain specific protein p25α (Lindersson et al., 2005) and
tubulin (Alim et al., 2002). Some post-trasductional modifications seem to enhance aS
fibril formation propensity. As an example, aS is predominantly present as non-
- 34 -
phosphorylated in normal in vivo conditions, but Ser129 phoshorylation forms occur in aS
inclusions in post-mortem patients brains (Fujiwara et al., 2002). In vitro, Ser129
phoshorylation was found to increase the formation of aS mature fibrils. The
demonstration of oxidatively nitrated aS in the syucleinopathic inclusions suggests that
oxidative insults may be relevant to the pathogenesis (Duda et al., 2000b; Giasson et al.,
2000). Moreover, aS modified by oxidative attachment of a dopamine adduct results in a
stabilization and subsequent accumulation of aS oligomers (Conway et al., 2001).
- 35 -
1.3. SYNUCLEIN AND LIPIDS
Although the regognized role of aS in neurodegeneration, its physiological
function remains poorly understood (Bendor et al., 2013). Recent studies pointed out that
aS interferes with vesicles-trafficking pathways (Lashuel et al., 2013). Scott and
colleagues, coupling α-synuclein overexpression and knock-out model-system, reported
that aS attenuates the mobility of recycling pool vesicles and maintains the overall size of
these vesicles. Specifically, overexpression of aS leds to smaller vesicles and inhibited
intersynaptic trafficking, while an absence of aS leads to larger vesicles size and enhanced
intersynaptic trafficking. (Scott et al., 2012). aS seems to have a chaperone activity, since
it directly binds SNARE-protein synaptobrevin-2/vesicle-associated membrane protein 2
(VAMP2) and promotes SNARE-complex assembly (Burrè et al., 2010). Moreover, in triple-
knockout mice, lacking synucleins, the absence of the proteins cause the development of
age-dependent neurological impairments, consinsting in decreased SNARE-complex
assembly, and premature death (Burrè et al., 2010). On the contrary, also membranes
seem to have an effect on aS, especially influencing its aggregation kinetic, with
difference depending on the membrane composition (Beyer et al., 2007).
1.3.1 Structural features
A variety of observations suggest that aS, in the cytosol, is normally divided
between a helix-rich, membrane-bound and a disordered cytosolic form, a behaviour
apparently conferred by structural similarity to the exchangeable apolipoproteins (Perrin
et al., 2000). Indeed, aS contains class A2 lipid-binding helices: similarly to this "class A2"
helical binding mechanism, lipid association is disrupted by introduction of charged
residues along the hydrophobic face of the predicted alpha-helix and also by biotinylation
of conserved lysines (which line the interfacial region). aS is able to undergo a large
conformational change in the presence of specific phospholipids, ability that is presumed
to be related to its functions (Perrin et al.,2000). Structural features of aS allow it to bind
to synthetic vesicles containing acidic phospholipids and to cellular membranes with
preferences towards acidic detergents like sodium dodecyl sulphate, and phospholipids,
like phosphatidylserine (PS), phosphatidylglycerol (PG) and phosphatidyc acid (PA)
composed vesicles, or mixture with neutral phospholipids (phosphatidylcholine (PC) and
phosphatilylethanolamine (PE)) (Davidson et al., 1998; Zhu & Fink, 2003; Zhu et al., 2003;
- 36 -
Rhoades et al., 2006). In presynaptic termini, monomeric α-synuclein exists in equilibrium
between free and membrane- or vesicle-bound states (McLean et al., 2000). This
equilibrium is tightly regulated, and it has been estimated that approximately 15% of α-
synuclein is membrane-bound within the synaptic termini (Lee et al., 2002). aS binding to
the membranes is accompanied by an increase in α-helix content (Perrin et al., 2000;
Davidson et al., 1998): different helical structures form upon membrane binding,
depending on the composition of the membrane. One well-studied form occured in the
presence of SDS micelles that led to the formation of two anti-parallel curved α-helices
(Val3-Val37 and Lys45-Thr92) connected by a well-ordered, extended linker, and followed
by another short extended region (Gly93-Lys97) (Ulmer et al., 2005). The well ordered
conformation of the helix-helix connector indicates a defined interaction with lipidic
surfaces. Other α-helix structure have been reported, such as a single curved α-helix
encompassing residues 1–90 (Jao et al., 2008; Lokappa and Ulmer, 2011). Also a non-
canonical α-helix model has been reported, characterized by a periodicity of 11/3 (Figure
1.9 incollata qui sotto), to better arrange to membrane placing lysine residues on the
interface between solvent and membrane surface: in this model lysine’s ε-amino groups
are responsible of the electrostatic interaction with negative charged headgroups of
phospholipids, while the acylic chain suits well in the hydrophobic environment due to
lipids tails (Bussell & Eliezer, 2003; Bussell et al., 2005; Jao et al., 2004; 2008).
- 37 -
Fig. 1.9. aS binding model to lipid vesicles. A and B are representations of the interaction of aS with a curved membrane. C is a more detailed view of this protein -lipid interaction. D schematic representation of aS structure on SUV or on micelles, that differs from large vesicles because highly curved micelles can not accomodate the extended helical structure as in A and B. E helical wheel in wich 11 amino acid residues make up three turns. In this way, a lipid-exposed side (red) and solvent-exposed side (green) are formed. F view of the overlaid structures from above the lipid surface. In blue, te 11 lysine residues, that are oriented approximately perpendicular to the helical axis (reprinted from Jao et al., 2008).
1.3.2 aS influence on lipid bilayers
aS interaction with membranes strogly influences the lipid bilayer structure
(Madine et al., 2006). Using 2H- and 31P-NMR spectroscopy it has been shown that the
association of aS with negatively charged membranes can disrupt the integrity of the lipid
bilayer, while it has little effect on membranes of zwitterionic phospholipids. (Madine et
al., 2006). Two different region of aS show preference for different membrane surface
charge: the peptide aS (10−48), a lysine-rich peptide of the N-terminal region, associates
with negative lipid, while peptide aS(120−140), a glutamate-rich peptide in the C-terminal
region, weakly associates with lipid headgroups but with a slightly higher affinity for
membranes with no net surface charge than for negatively charged membrane surfaces.
Binding of these peptides to lipid vesicles do not disrupt the lamellar structure of the
- 38 -
membranes, but both peptides induce the lateral segregation of the lipids into clusters of
acidic lipid-enriched and acidic lipid-deficient domains. This finding is really important
because it could reveal the function of aS: it has been speculated that the N-terminal and
C-terminal domains of aS might act in concert to organize membrane and play a role in
presynaptic vesicle synthesis, maintenance, and fusion (Madine et al., 2006). Another
consequence of aS bound to lipids that could be related to aS function, is the prevention
of lipids oxidation (Breydo et al., 2012). The antioxidant function of aS could be attributed
to its facile oxidation via the formation of methionine sulfoxide. Monitoring the lipid
oxidation kinetics in the absence and in the presence of aS, Zhu et colleagues find that
monomeric aS prevent unsaturated lipid oxidation while aS fibrils do not (Zhu et al.,
2006). The inhibition of lipid oxidation by aS may be a physiological function of the
protein (Zhu et al., 2006).
1.3.3 Lipids influence on aS properties
Membranes and aS fibrillogenesis are correlated in two ways: lipids influence aS
aggregation and, viceversa, oligomeric species of aS seem to exert their toxic activity on
membranes. aS-lipids interaction, causing rearrangement of the structure of aS,
influences aS aggregation kinetic. Indeed, it has been reported that the interaction of α-
synuclein with the membranes alters the kinetics and pathways of its aggregation in vitro
(Breydo et al., 2012). Lipids seem to act as anti-chaperones facilitating protein transition
into partially folded states more prone to aggregate. The effects of membrane binding
varied, from inhibition (Zhu and Fink 2003) to acceleration (Necula et al., 2033) of aS
aggregation, (Zhu et al., 2003a; Zhu et al., 2003b)and (Jo et al., 2000). These opposite
effects primarly depend on the protein-lipid molar ratio. Low concentration of fatty acids
accelerate aggregation of aS (Necula et al., 2003), probably because membrane-bound α-
synuclein can generate nuclei that seed the aggregation of the more abundant cytosolic
form (Lee et al., 2002). On the contrary, higher fatty acids concentration induces total aS
conversion to the α-helical membrane-bound form, that is unlikely to contribute to
aggregation and fibril formation (Zhu et al., 2003b). These observations suggest that the
initial phases of aS aggregation may occur on the surfaces of membranes and thus
pathological conditions that induce cross-linking of synuclein, such as oxidative stress,
may enhance the propensity for aggregation (Cole et al., 2002). Indeed, detection of
- 39 -
oligomeric form of aS formed in the presence of lipids has been reported both in vivo and
in vitro (Sharon et al., 2003; De Franceschi et al., 2011). Specifically, polyunsaturated fatty
acid (PUFA), such as arachidonic and docosahexaenoic acids, have been linked to aS
oligomerization, also at physiological concentrations (Perrin et al., 2001). However, it has
been reported that experimental conditions strongly influenced the structure and
heterogenicity of oligomers of aS formed in the presence of lipids (Haque et al., 2010).
1.3.4 Role of fatty acids
Multiple studies have documented interactions of aS with free fatty acids, but the
physiological consequences are still not fully understood (Ruipérez et al., 2010). Perrin
and coworkers (2001) showed that in vitro exposure to vesicles containing certain
polyunsaturated fatty (PUFAs) causes the formation of aS oligomers at physiological
concentrations. It has been reported that aS interacts with PUFAs in vivo to promote the
formation of highly soluble oligomers that precede the insoluble aS aggregates associated
with neurodegeneration . Indeed, soluble oligomers of aS were found in the cytosol of
mesencephalis neuronal cells derived from murine (normal or aS-transgenic) and human
(normal or PD affected) brains. Interestingly, exposure of cells to PUFAs increased aS
oligomers levels, while saturated or monounsaturated FAs did not. In addition to the
degree of saturation, the length of the carbon chain was important for alpha-synuclein
oligomerisation (Sharon et al., 2003). These results have been confirmed in vitro: PUFAs,
depending on unsaturation and carbon chain length, influence aS aggregationlead to the
formation of cytotoxic oligomers (Assayag et al., 2007). Upon interaction with DHA, the
normally unstructured α-synuclein rapidly adopts an α-helical conformation. This effect
has been observed in the presence of both arachidonic acid or docosahexaenoic acid, but
not in the presence of saturated fatty acids (Broersen et al., 2006). The study of DHA is
especially important since DHA accounts for 60% of all esterified fatty acids in neuronal
plasma membrane (Lukiw et al., 2008). Moreover, the levels of this fatty acid in a non-
esterified form appear to be elevated in patients affected by Parkinson’s disease (Sharon
et al., 2003) and it has also been reported that DHA intake increases expression of aS
gene, and in turn aS allows DHA to be present in a soluble rather than micellar form. For
these reasons, interest growth on the study of the mode of interaction of aS and DHA: It
has been reported that the N-terminal alpha-synuclein fragment of approximately 70–80
- 40 -
amino acids was most resistant to proteolysis in the presence of docosahexaenoic acid,
suggesting that PUFAs interact with the N-terminus of the protein (De Franceschi et al.,
2009). Recent studies implicated aS specifically in regulation of fatty acid metabolism.
Mice lacking the alpha-synuclein gene exhibited reduced incorporation of arachidonic
acid (AA) into brain phospholipids, and a simultaneous riseof about 50% in incorporation
of docosahexaenoic acid (Golovko et al., 2007). Because AA and DHA are the major
polyunsaturated fatty acids in the brain, the increase in DHA incorporation into brain
phospholipids is considered to be compensatory for the reduction in rate of AA
incorporation into these lipid pools, since both FAs use the same sn-2 position of
phospholipids. Further genetic studies in mice have suggested a role for alpha-synuclein
in substrate presentation to acyl-CoA synthetase (ACSL), a critical enzyme in the fatty acid
re-acylation pathway. The ablation of alpha-synuclein decreased ACSL activity (Golovko,
et al., 2006). Importantly, addition of physiologically relevant concentrations (3.15–6.3
nM) of aS WT, but not mutant aS, restores AA-CoA formation in aS KO mice: mutant
forms of aS (A30P, E46K, and A53T) fail to modulate acyl-CoA synthetase (Acsl) activities,
indicating that expression of these forms may cause a loss of function. Alpha-synuclein
was shown to specifically modulate activity of the ACSL6 isoform which is responsible for
arachidonic acid incorporation into phospholipids (Golovko et al., 2009). Since aS is a FA
binding protein, several studies analyzed consequences on FA incorporation in the
absence of aS. Barcelo and colleagues reported that in ethanolamine
glycerophospholipids and phosphatidylserine, docosahexaenoic decreases of about 7%
(Barcelo-Coblijn et al., 2007). Into astrocytes of WT and aS-KO mice (68), aS deficiency
decreased PA and AA incorporation of about 31% and 39%, respectively, while DHA
incorporation was unaffected. In the phospholipid fraction, a decreased distribution into
this lipid pool of these fatty acids, including DHA, was found (Castagnet et al., 2005). In
cells treated with high concentrations of fatty acids, aS WT was found to associate also
with lipid droplets, specifically it seems to accumulate on phospholipid monolayers
surrounding triglyceride-rich lipid droplets and was able to protect stored triglycerides
from hydrolysis (Cole et al., 2002). Treatment of aS-expressing HeLa cells with high levels
of oleic acid, determined an increase in the formation of lipid droplets and translocation
of aS from the cytosol to the surface of lipid droplets. Interestingly, PD mutant synucleins
showed variable distributions on lipid droplets and were less effective in regulating
- 41 -
triglyceride turnover. Also small aS oligomers detected in cells, primarily dimers and
trimers, were associated with lipid droplets and cell membranes, suggesting that the
initial phases of synuclein aggregation may occur on the surfaces of membranes (Cole et
al., 2002). Another important aspect involving FA is the oxidative stress damage. Neurons
are particularly susceptible to injury by oxidative stress beacuse of low defence
mechanisms and the high rate of oxygen consumption (Ruiperez et al., 2011). Among
brain lipids, PUFAs are particularly vulnerable to oxidation due to their unsaturated bonds
(Fig. 1.10). Of note, several studies suggest that aS may be neuroprotective toward
oxidative stress. Indeed, aS levels increase in neurons exposed to chronic oxidative (Quilty
et al., 2006) However, these study do not expalin whether these aS changes are cytotoxic
or neuroprotective. It was
also proposed that aS
could directly prevent
oxidation of PUFA, via the
formation of methionine
sulfoxide, acting as
scavengers of ROS (Zhu et
al., 2006). These findings
suggest that the inhibition
of lipid oxidation by α-
synuclein may be a
physiological function of
the protein. Fig. 1.10. Metabolism of polyunsaturated fatty acids (PUFAs). PUFAs are released from phospholipid membranes through the action of PLA2. Alpha-synuclein (αS) binds free PUFAs changing its conformation. PUFAs are reincorporated into phospholipids through the action of acyl-CoA synthetases (ACSL) and lysophosphatidyl acyltransferases (LPAT). PUFAs are also transported into mitochondria (bottom left) for degradation generating ATP with a minor production of reactive oxygen species (ROS). PUFAs can be oxidized into eicosanoids through enzymatic actions and also converted into oxidized species in uncontrolled ROS reactions. The interaction of alpha-synuclein with PUFAs (oxidized or not) could lead to mitochondrial changes. Proteins Parkin, DJ-1, PINK1 and LRKK2 are implicated in the regulation of mitochondrial functions. Mutations in these proteins lead to inherited Parkinson’s disease (reprinted from Ruiperez et al., 2011).
- 42 -
- 43 -
2. Materials and Methods
2.1 Materials DHA and fluorescein isothiocyanate dextran (FITC-Dextran) of average molecular
weight of 10,000 Da were purchased from Sigma Chem. Co. (St. Louis, MO). Trypsin from
bovine pancreas, and thioflavin-T (ThT) were purchased from the Sigma Chemical
Company (St. Luis, MO), whereas acetonitrile and triluoroacetic acid (TFA) from Fluka
(Buchs, Switzerland). All other chemicals were of analytical reagent grade and were
obtained from Sigma or Fluka.
The lipids, 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC), 1,2-dioleoyl-sn-
glycero-3-phospho-(1'-rac-glycerol) (DOPG), 1-palmitoyl-2-oleoyl-sn-glycero-3-phospho-L-
serine (POPS), 1-palmitoyl-2-oleoyl-sn-glycero-3 phosphoethanolamine (POPE) and Brain
Total Lipid Extract, were obtained from Avanti Polar Lipids (Alabaster, AL) as chloroform
solution and used without further purification.
2.2 Methods 2.2.1 Expression and purification of recombinant aS and aS mutants
Human aS cDNA was amplified by PCR with synthetic oligonucleotides (Sigma-
Genosys) containing NcoI and XhoI restriction sites and designed to obtain the entire
sequence of the protein (aS/E46K/A30P/A53T/H50Q 1-140). After digestion with
restriction enzymes, the two PCR products were subcloned into the NcoI-XhoI-linearized
pET28b expression plasmid (Novagen) and introduced into an Escherichia coli BL21(DE3)
strain.
Overexpression of proteins was achieved by growing cells in LB medium (1% Bacto
tryptone, 0.5% yeast extract, 0.5% NaCl) at 37 °C to an OD600 of 0.6-0.8 followed by
induction with 0.5 mM isopropyl β-thiogalactopyranoside for 4 h.
The purification of aS and its mutants was conduced following this procedure. After
osmotic rupture of cells, centrifugation was used to separate lipid and contaminants.
After boiling of cell proteic content for 15 min, the soluble fraction, containing the
protein, was treated with 55% ammonium sulphate. The pellet was then resuspended,
dialyzed and loaded into a Resource Q 6-ml column (Amersham Biosciences) and then
eluted using 20 mM Tris buffer, pH 8, with a linear gradient 0-500 mM NaCl.
Further purifications were obtained by RP-HPLC. aS was purified in a Jupiter-C4 column
(4.6 x 150 mm) (Phenomenex, CA, USA) eluted with a linear gradient of water (0.1 % TFA),
versus acetonitrile (0.085 % TFA) from 5% to 38% in 5 min and from 38% to 43% at a flow
rate of 0.6 ml/min. All aS mutants were expressed and purified following the same
protocol. Finally, the proteins were lyophilized and stored at -20 °C.
2.2.2 Aggregation studies
In order to analyze the aggregation process of aS, lyophilized protein obtained
from purification was dissolved in PBS phosphate buffer (8 mM Na2HPO4, 137 mM NaCl,
2 mM KH2PO4, 2.7 mM KCl), pH 7.4, and filtering the protein solution with a 0,22 μm
pore-size filter (Millipore, Bedford, MA, USA). Dissolved samples were incubated at 37 °C
at a protein concentration of 50 μM (0.723 mg/ml), under shaking at 500 rpm with a
thermo-mixer (Compact, Eppendorf, Hamburg, DE). The same experiment has been
conduced in parallel for A30P, A53T, E46K and H50Q mutants, with or without DHA.
- 44 -
2.2.3 Circular Dichroism
Protein concentrations were determined by absorption measurements at
280 nm using a double-beam Lambda-20 spectrophotometer from Perkin Elmer (Norwalk,
CT). The extinction coefficients at 280 nm were 5960 M-1 for aS and mutants, as evaluated
from their amino acid composition by the method of Gill and von Hippel (1989).
Circular dichroism spectra were recorded on a Jasco J-710 (Tokyo, Japan)
spectropolarimeter. Far-UV CD spectra were recorded using a 1 mm path-length quartz
cell and a protein concentration of 5 µM. The mean residue ellipticity [θ] (deg⋅cm2⋅dmol–
1) was calculated from the formula [θ] = (θobs/10) ⋅(MRW/lc), where θobs is the observed
ellipticity in deg, MRW is the mean residue molecular weight of the protein, l the optical
pathlength in cm and c the protein concentration in g/mL. The spectra were recorded in
PBS buffer, pH 7.4, both in the presence of different concentration of DHA (ranging from
0-400 µM) and during aggregation studies.
2.2.4 Gel filtration
Gel filtration chromatography (or size exclusion chromatography) was performed
with a Superdex 75 10/300GL column (Amersham Biosciences, Uppsala, Sweden), using
an ÄKTA FPLC system (Amersham Biosciences, Uppsala, Sweden). The matrix is composed
of cross-linked agarose and dextrane with an average particle size of 13 μm and a 3-70
KDa separation range for globular proteins. The hydrodynamic volume of analytes was
determined on the base of the the distribution coefficient, Kd, calculated as the following
formula: Kd= (Ve-Vo)/(Vt-Vo), where Ve, Vt and Vo are respectively the analyte elution
volume, total and void volume. If the analyte is large and completely excluded from the
mobile phase within the gel, Kd = 0 whereas, if the analyte is sufficiently small to gain
complete access to the inner mobile phase, Kd = 1. Due to variation in pore size between
individual gel particles, there is some inner mobile phase that will be available to analytes
of intermediate size; hence Kd values vary between 0 and 1. It is this complete variation
of Kd between these two limits that makes it possible to separate analytes within a
narrow molecular size range on a given gel.
A calibration controls with globular proteins of known MW was performed. 50 µg of each
of the following standard calibration proteins were loaded: bovine α-lattalbumine (MW=
14 kDa), carbonic anhidrase (MW= 29 kDa), ovoalbumin (MW= 45 kDa), BSA(MW= 66
kDa), thyroglobulin (MW= 440 kDa) , β-amilase (MW= 200 kDa) and ferritin (MW= 669
kDa). 200 µg of blue dextran and 0.05% dimethyl sulfoxide (DMSO) were loaded to
estimate the void and total volume of the column, respectively. The elution was
monitored by recording on-line the absorbance at 214 nm. In order to characterize aS and
its mutants behaviour in solution, 144 µg of proteins at different time of incubation were
loaded.
2.2.5 RP-HPLC
Reversed-phase high-performance liquid chromatography (RP-HPLC) involves the
separation of molecules on the basis of hydrophobicity. The separation depends on the
hydrophobic binding of the solute molecule from the mobile phase to the immobilized
hydrophobic ligands (n-butyl, n-octyl and n-octadecyl) attached to the stationary phase.
This one usually consists of an n-alkylsilica-based matrix from which the solutes are eluted
with gradients of increasing concentrations of organic solvent such as acetonitrile. A
charged ion-pairing reagent (TFA, trifluoroacetic acid) with an opposite charge to that of
- 45 -
the protein is added to the mobile phase to form a noncharged complex. TFA increases
the idrophobicity and consequently the retention of the protein, indeed if it is added in a
concentration of 0.085% (v/v), the pH is around 2.5. At this pH, the carboxylic groups of
protein are protonated and the trifluoroacetic anion binds to the positively charged
amino groups of proteins. Elution proceeds by application of a gradient of increasing
organic solvent concentration, which competes with the stationary phase for hydrophobic
interaction with the analyte.
The HPLC analyses of aggregated samples were conducted using a Jupiter C4 column (4.6
mm × 150 mm; Phenomenex, CA, USA), eluted with a gradient of water/0.1% TFA vs
acetonitrile/0.085% TFA from 5% to 38% in 5 min, from 38% to 43% in 15 min. The elution
was monitored by recording the absorbance at 226 nm. The identity of the eluted
material was assessed by mass spectrometry.
2.2.6 SDS-PAGE
SDS-PAGE was conducted following the method of Laemmli (1970). In SDS
polyacrylamide gel electrophoresis (SDS-PAGE), charged proteins migrate in response to
an electric field. Their rate of migration depends on the strength of the field and on the
net charge, size and shape of the molecules. Since different proteins with similar
molecular weights may migrate differently due to their differences in secondary, tertiary
or quaternary structure, sodium dodecyl sulphate (SDS), an anionic detergent, is used in
SDS-PAGE to reduce proteins to their primary (linearized) structure and coat them with
uniform negative charges. Polyacrylamide gels restrain larger molecules from migrating as
fast as smaller molecules. Because the charge-to-mass ratio is nearly the same among
SDS-denatured polypeptides, the final separation of proteins is dependent almost entirely
on the differences in relative molecular mass of polypeptides. Electrophoresis
experiments were conducted with the Mini-Protean II electrophoresis system purchased
from Biorad using plates of 5 x 8 cm and spacer of 0.75 mm thickness. For the separation
of proteins the gel was composed by 13 % T (% total acrylamide and bis-acrylamide). The
electrophoretic buffer (Laemmli buffer) composition was: 25 mM Tris-HCl, 0.25 M glycine,
0.1% SDS, pH 8.5. The acrylamide polymerization was obtained by adding TEMED and 10%
solution of ammonium persulfate (APS). Samples were dissolved in 50 mM Tris-HCl, pH
6.8, containing 2% SDS, 2% β-mercaptoethanol, 10% glycerol, traces of bromophenol blue
and denaturated by heating at 100 °C for 5 minutes. The electrophoresis was performed
at room temperature at 25 mA.
2.2.7 Native-PAGE
Native (non-denaturing) polyacrylamide gel electrophoresis was conducted with
the Mini-Protean II electrophoresis system purchased from Biorad using plates of 5 x 8 cm
and spacer of 0.75 mm thickness. For the separation of proteins the gel was composed by
13 % T (% total acrylamide and bis-acrylamide). The electrophoretic buffer composition
was: 25 mM Tris-HCl, 0.25 M glycine, pH 8.5. Samples were dissolved in 50 mM Tris-HCl,
pH 6.8, containing 10% glycerol and traces of bromophenol blue. The electrophoresis was
performed at room temperature at 25 mA.
- 46 -
2.2.8 Liposomes preparation
To prepare large and small unilamellar vesicles (LUV, SUV), lipids were transferred
in glass tubes. Chloroform was dehydrated by gentle helium stream and then warmed at
45°C to remove residual organic solvent. The lipid film was hydrated with PBS pH 7.4 in
the absence or presence of calcein (50 mM) or FITC-dextran (1.6 mM) at 40°C for 2 hours
with frequent vortexing. Then it was subjected to 5 cycles of freezing and thawing. The
suspension vesicles was extruded 11 times through a 400 nm or 30 nm pore size
polycarbonate membrane on lipid extruder (Northern Lipids Inc, Vancouver, BC), in order
to obtain LUVs or SUVs. Calcein-loaded and FITC-dextran-loaded vesicles were purified by
gel filtration chromatography (Sepharose G-25) to remove unencapsulated dye. The final
lipid concentration, determined as total phosphorus, was conducted according to Chen et
al.2003.
2.2.9 Thioflavin T binding assay (ThT)
The ThT binding assays were performed accordingly to LeVine (1993) using a
freshly prepared 25 µM ThT solution in 25 mM sodium phosphate (pH 6.0) that had been
passed through 0.45 µm filters. Aliquots (30 µl) of protein samples from the aggregation
incubation were taken at specified times and diluted into the ThT buffer (final volume 500
µl). Fluorescence emission measurements were conducted at 25°C using an excitation
wavelength of 440 nm and recording the ThT fluorescence emission at 480 nm.
2.2.10 Dynamic Light Scattering (DLS)
DLS measurements were carried out with a Zetasizer Nano-S instrument (Malvern
Instrument, UK). This apparatus, which uses the backscattering detection (scattering
angle θ=173°) and an avalanche photodiode detector (APD), is equipped with a Helium–
Neon laser source (wavelength 633 nm; power 4.0 mW), and a thermostated sample
chamber controlled by a thermoelectric Peltier. DLS measurements were performed at
25°C in PBS pH 7.4 in duplicate. During every measurement 12 runs were collected.
DLS was used to check the size distribution and the stability of vesicles. DOPG LUV and
SUV size distributions were measured for vesicles alone and after 30 min of incubation
with oligomers.
2.2.11 Transmission Electron Microscopy
In order to evaluate the morphology and the size of the species deriving from the
self-assembly of DHA and from the aggregation process of aS, aliquots of the samples
were examined by transmission electron microscopy (TEM). The samples relative to
aggregation of the proteins were diluted 3 times with PBS. A drop of the samples solution
was placed on a Butvar-coated copper grid (400-square mesh) (TAAB-Laboratories
Equipment Ltd, Berks, UK), dried and negatively stained with a drop of uranyl acetate
solution (1%, w/v). TEM pictures were taken on a Tecnai G2 12 Twin instrument (FEI
Company, Hillsboro, OR, USA), operating at an excitation voltage of 100 kV.
2.2.12 Mass spectrometry
Mass determinations were obtained with an electrospray ionization (ESI) mass
spectrometer with a Q-TOF analyzer (Micro) from Waters Micromass (Manchester, UK).
The measurements were conducted at a capillary voltage of 3 kV and a cone voltage of 35
- 47 -
V. The molecular masses of protein samples were estimated using the Mass-Lynx
software 4.1 (Micromass).
2.2.13 Proteolysis
Proteolysis experiments were carried out on monomeric aS and aS mutants to
analyze interaction with DHA, using proteinase K (Ebeling et al., 1974) at E/S ratio of
1:1000 (by weight). Experiments of proteolysis were conducted also on oligomeric
samples of aS/DHA and H50Q/DHA, to identify aminoacidic residues modified by DHA,
using Trypsin at a E/S ratio of 1:100 (by weight). All experiments were conduced in PBS,
pH 7.4 and the reactions were quenched at specified times by acidification with TFA in
water (4%, v/v) or by direct injection in RP-HPLC. All the proteolysis mixtures were
analyzed by RP-HPLC. For all the proteins, the RP-HPLC analyses were conducted using a
Vydac C18 column (4.6 mm x 250 mm; The Separations Group, Hesperia, CA), eluted with
a gradient of water/0.1% TFA vs. acetonitrile/0.085% TFA from 5% to 25% in 5 min, from
25% to 28% in 13 min, from 28% to 39% in 3 min, from 39% to 45% in 21 min at a flow
rate of 1 ml/min. Column was provided by a HPLC security guard column SAX
(Phenomenex, USA). The sites of cleavage along the polypeptide chains were identified by
mass spectrometry analyses of the protein fragments purified by RP-HPLC.
2.2.14 Ion exchange chromatography
Separation in ion exchange chromatography depends upon the reversible
adsorption of charged solute molecules to immobilized ion exchange groups of opposite
charge. Separation is obtained since different substances have different degrees of
interaction with the ion exchanger due to differences in their charges, charge densities
and distribution of charge on their surfaces. An ion exchanger consists of an insoluble
matrix to which charged groups have been covalently bound. The charged groups are
associated with mobile counter ions which can be reversibly exchanged with other ions of
the same charge without altering the matrix. After sample injection, solute molecules
carrying the appropriate charge displace counter-ions and bind reversibly to the gel,
whereas unbound substances are washed out from the exchanger bed using starting
buffer. Desorption of solute molecules is achieved by increasing the ionic strength of the
eluting buffer.
The analyses of aS and aS/DHA were conducted using a Resource-Q column (Amersham
Pharmacia), a strong anion column pre-packed with SourceTM. SourceTM is based on
monodisperse, hydrophilized and rigid polystyrene/divinyl benzene beads, produced by
substitution of the base matrices with quaternary amino groups (-O-CH2-CHOH-CH2-O-
CH2-CHOH-CH2-N+(CH3)3). The eluting buffer used was 20 mM Tris pH 8 with a 30-
minutes linear gradient 150-500 mM NaCl.
2.2.15 DNPH assay
2,4-Dinitrophenylhydrazine (DNPH) or Brady's reagent is a substituted hydrazine
used to detect, in lateral chain of aminoacids, carbonyl groups such as aldehydes and
ketones. aS monomers and aS/DHA oligomers purified by RP-HPLC were dried and
resuspended in 2M HCl + 10mM DNPH, and then incubated for 1h at room temperature
in the dark. To stop reaction, proteic material was precipitated with 15% trichloroacetic
acid. After centrifugation, pellets were washed 3 times with a solution of ethanol:ethyl-
acetate 1:1 and then dried. For RP-HPLC analysis, samples were re-hydrated in 0.1% TFA
- 48 -
and chromatograms were recorded both at 226 nm (to detect the proteic material) and
366 nm (to detect DNPH). Eluted fractions were analyzed by mass-spectrometry. For UV-
Vis analysis, samples were resuspended in 6M Guanidinium chloride overnight and
spectra were recorded from 380to 240 nm.
2.2.16 Atomic Force Microscopy
aS/DHA oligomers were diluted 500 times using Milli-Q water and 10 µl aliquots
were deposited on freshly cleaved mica and dried under mild vacuum. Tapping mode
AFM images were acquired in air using a Multimode scanning probe microscope equipped
with an “E” scanning head (maximum scan size 10 µm) and driven by a Nanoscope IV
controller (Digital Instruments, Bruker, Germany). Single beam uncoated silicon
cantilevers (type Olympus OMCL-AC160TS, Olympus, Tokyo, Japan) were employed. The
tip of the probe was of 7 nm.The drive frequency was between 280 and 300 kHz, and the
scan rate was between 0.5 and 1.0 Hz. TEM pictures were taken on a Tecnai G2 12 Twin
instrument (FEI Company, Hillsboro, OR, USA), operating at an excitation voltage of 100
kV. Samples for TEM were diluted 2 times and a drop of the solution was placed on a
Butvar-coated copper grid (400-square mesh) (TAAB-Laboratories Equipment Ltd, Berks,
UK), followed by a drop of uranyl acetate solution (1% w/v).
2.2.17 Release Assays
For calcein release assay, SUV or LUV were diluted to 50 µM of lipids. After 30
minutes of incubation in the presence of different protein species (monomers, oligomers,
fibrils), fluorescence emission at 515 nm was recorded after excitation at 490 nm.
Maximum fluorescence emission was obtained by the addition of 0.1% Triton X-100 to
disrupt vesicles. The average values of experiments, performed in triplicate, were
expressed as a percentage of the maximum effect due to total vesicles disruption. FITC-
dextran-loaded SUVs or LUVs were incubated for 30 minutes in the presence of the
protein species at a final lipid concentration of 100 M. Released dye was detected by
fluorescence measurement with excitation at 490 nm and emission at 515 nm, after
purification of the incubated solution through Microcon (cutoff 50000) to allow FITC-
Dextran elution. The minimum and maximum effect was obtained by measurement of a
liposome solution respectively with or without 0.1% Triton X-100. The average values of
experiments, performed in triplicate, were expressed as a percentage of the maximum
effect calculated as total vesicles disruption obtained with Triton X-100.
2.2.18 Cell Permeabilization Assay
To examine whether aS/DHA oligomers can permeabilize cell membranes, we
exploited the ability of propidium iodide (PI; MW 668.4 Da) to bind DNA as indirect
reporter of membrane damage. Dopaminergic SH-SY5Y cells were cultured in 24-well
plates (seeding density ~50000 cells/well) and twenty-four hours after seeding treated
with 0.5 µM of aS monomer or aS/DHA oligomers. Impermeant dye PI (2 µg/ml) and
counterstain dye Hoechst 33242 (2 µg/ml) were added to cells simultaneously to the
treatment. After a 30 min-incubation at 37°C, PI-positive cells were counted in three
replicate cultures, acquiring an average of 5 fields per culture (250-350 cells/field). The
experiment has been repeated 3 times independently. Saponin (50 µg/ml) was used as
positive control of membrane permeabilization.
- 49 -
2.2.19 Planar Lipid Membrane
Solvent-free Planar Lipid Membrane (PLM) was composed of equimolar mixture of
1,2-dioleyl-phosphatidyl-glycerol (DOPG) and 1,2-dioleyl-phosphatidyl-ethanolamine
(DOPE) and formed on an aperture in a 25 µm thick Teflon septum separating two
chambers, as described in Dalla Serra et al. [26]. Ionic currents were recorded by a patch
clamp amplifier (VA-10X npi, Tamm, Germany), filtered at 100 Hz, digitalized and acquired
at 2 kHz by the computer using DigiData 1322 A/D converter and pClamp software (Axon
Instruments, Sunnyvale, CA).
- 50 -
- 51 -
3. aS/DHA OLIGOMERS CHARACTERIZATION
Multiple studies have documented interactions of aS with phospholipid
membranes and free fatty acids even if the physiological consequences are not still
understood. In vivo, almost the 15% of aS is supposed to be bound to lipid membranes
(Lee et al., 2002). This binding leads the protein to acquire α-helix structure and can have
consequences on its aggregation kinetic, inducing protein oligomerization or preventing
amyloid formation (Breydo et al., 2012). As previously reported (Sharon et al., 2003; De
Franceschi et al., 2011), aS is able to bind brain fatty acid, such as DHA. We and others
have shown that in the presence of DHA aS acquires α-helix structure and undergoes
aggregation that rapidly leads to the formation of stable oligomers, that are toxic to cells
(De Franceschi et al., 2011). A study on the kinetic of aggregation and on the properties of
the species formed in the presence of DHA has been conducted by our group in a
previous work, but some aspects remained unclear. Considering that the main objective
of the present research was to define the activity of the oligomers formed in presence of
DHA, a further characterization has been conducted. In particular, a new method for the
isolation of the oligomers based on ion exchange chromatography have been proposed as
alternative to the gel filtration. Other relevant aspects of this study regard the chemico-
psysical characterization of the oligomers by using microscopy and spectroscopic
techniques. Finally a large part of the research is dedicated to the analysis of the activity
of oligomers on model membranes and cells to the aim to propose a possible mechanism
of toxicity.
3.1 Aggregation process of aS in the presence of DHA and isolation of
oligomers
aS aggregation is conducted in the presence of DHA, using a molar ratio
protein:fatty acid of 1:50. Previously it was found that it was possible to monitoring the
aggregation and to isolate oligomeric aS from monomeric one using gel filtration
chromatography. In Fig. 3.1 the main points of the purification and chemical
characterization are reported. The mixture of aS and DHA corresponding to 48 hours of
incubation was used for the studies conducted here. The monomeric species elutes at 24
min, (Fig. 3.1 A). The oligomeric species (Fig. 3.1 A, dashed line), that elutes at 20 min,
- 52 -
increases on time. This fraction was analyzed by RP-HPLC for its identification and to
provide further information about the chemical properties of oligomers (Fig. 3.1 B).
Fig. 3.1. Gel filtration (A) and RP-HPLC (B) chromatograms of aS/DHA mixture. (A) Gel filtration
of aS in the absence (solid line) and in the presence (dashed line) of DHA in a molar ratio
protein:lipid of 1:50. (B) RP-HPLC analyses were conducted using a Jupiter C4 column (4.6 x 150
mm; Phenomenex, CA, USA), eluted with a gradient of acetonitrile/0.085% TFA vs water/0.1% TFA
from 5% to 38% in 5 min, from 38% to 43% in 15 min, recording the absorbance at 226 nm. The
identity of the eluted material was assessed by mass spectrometry and the spectrum of oligomers
(RT 29.5) is reported (inset).
RP-HPLC chromatograms of aS/DHA mixture after 48 hours of incubation shows
the presence of the peak relative to oligomer eluting at 29.5 min and two peaks at higher
retention time corresponding to DHA and DHA by-products. Oligomeric fraction eluted by
gel filtration, shows the same species at 29.5 min but the other two peaks are absent,
indicating that the GF step removes the free fatty acid. Mass spectrometry analysis of
species eluted at 29.5 min (Fig. 3.1 B, inset) shows that aS contains methionine oxidations
and a covalent bound DHA molecule as indicated by the mass increase of 326 Da on the
expected mass (14460 Da). The modification is not present in all molecules but from
electrospray mass spectrometry data a modification of about 3% can be hypothesized.
Gel filtration is resulted highly suitable for the purification of aS oligomers since
that it is possible to remove aS in monomeric form and the excess of DHA. Moreover the
native elution conditions, phosphate buffer at pH 7.5, seems to not induce chemical
stress of the protein species. The main drawback of this type of method is the dilution of
Retention Time (min)10 15 20 25 30
Rel
ativ
e A
bsor
banc
e at
214
nm
Retention Time (min)10 15 28 32
Relative A
bsorbance at 226 nm
aS/DHA oligomers
DHA products
DHA
Mass (KDa)14.5 14.6 14.7 14.8 14.9
Rel
ativ
e In
tens
ity
14476
14492
14508
14802
14817
14831
14859
14864
14880
A B
- 53 -
the sample in the purified fraction. This could affect the dynamic equilibrium between the
monomeric and aggregated form of aS. Due to the too low protein concentration in the
purified sample, further analyses, such as structural characterizations and functional
tests, are sometimes difficult to perform. So we tried another method of isolation based
on ion exchange chromatography (IEX). The benefits of IEX are that it has a high
throughput, the column has a long lifespan and it has a high resolving power allowing the
separation of proteins having isoelectric points differing about 0.5 units of pH. So in this
case we can have also information about change in the charge properties of the
oligomers. In general separations can be fast, recoveries are high, buffer components are
non-denaturing and frequently compatible with further downstream chromatographic
separation or assay systems. Moreover this technique provides information on the
possible charge modifications on the polypeptide chain of aS. Finally, it can be used as a
concentration step, to recover proteins from a dilute solution.
aS/DHA mixture were loaded in an anion-exchanger column and to compare
elution pattern also the monomeric aS was analyzed as reference (Fig. 3.2). aS elutes at
12 min and after 48 hours of incubation there is no further peak in the chromatogram
(Fig. 3.2 A). The analysis of the mixture aS/DHA just after its preparation shows the same
peak at 12 min, but after incubation, there are two main peaks at 12 and 20 min
corresponding to 44% of NaCl in the chromatogram (Fig. 3.2 B). In order to identify the
material under the peaks, these two main fractions were analyzed by RP-HPLC (Fig. 3.2 C)
and they correspond respectively to monomeric and oligomeric aS. The late elution of the
oligomers can be explained as higher affinity of these species for DEAE resin than the
monomer. The resin is positively charged, so the affinity of aS presumably derives from
the negatively charged C-terminal tail. The oligomers are formed by several monomer aS
molecules, whose negatively charged C-terminal tails are not expected to be involved in
the oligomer structure (De Franceschi et al., 2009), but they are free to interact with the
anion exchanger. Moreover, also the presence of bound DHA could provide additional
negative charge. The peak corresponding to oligomer seems narrow suggesting that the
purified population of oligomers might be almost homogenous in terms of net charge.
Unfortunately technical problems hampered the extensive use of this chromatography.
Indeed it is resulted partially non-reproducible especially in terms of yield. For this reason
we decided to continue to purify oligomers by gel filtration.
- 54 -
Fig. 3.2. IEX chromatography of aS (A) and aS/DHA 1:50 (B). The IEX chromatograms were
obtained from samples just prepared (dashed line)) and after 48 hours of incubation (solid line).
IEX analyses were conducted using a DEAE column, eluted with a gradient of NaCl from 0 to 1M in
30 minutes, recording the absorbance at 214 nm. (C) RP-HPLC chromatogram of fractions eluted
at 12 min (dashed line) and 20 min (solid line) in IEX of aS/DHA after 48 hours. (C) RP-HPLC
analyses were conducted using a Jupiter C4 column (4.6 x 150 mm; Phenomenex, CA, USA), eluted
with a gradient of acetonitrile/0.085% TFA vs water/0.1% TFA from 5% to 38% in 5 min, from 38%
to 43% in 15 min, recording the absorbance at 226 nm.
- 55 -
3.2 Chemico-physical characterization of aS/DHA oligomers
aS/DHA oligomers were characterized by far-UV CD. The mixture corresponding to
different times of incubation was analyzed. aS acquires α-helix structure in the presence
of DHA and this type of secondary structure is maintained during oligomerization process
(Fig. 3.3 A). Upon incubation, a small decrease of signal is detectable, as a consequence of
aggregation and probable precipitation of the protein material.
Fig. 3.3. Far-UV CD spectra. (A) aS/DHA mixture during the aggregation process. The spectra were
recorded at a protein concentration of 5 mM in PBS pH 7.4, immediately after addition of DHA,
and after 3, 24 and 48 hours. (B) Far UV CD of oligomers after purification by gel filtration (red
line). The spectra of monomeric aS and aS in the presence of DHA (protein/DHA 1:50) are also
reported as reference. (C) Titration experiment by far UV CD of oligomers in the presence of
increasing amount of DHA. The numbers close to the spectra indicate the amount (µM) of DHA.
The secondary structure of oligomers was checked also after the purification step by
gel filtration. Oligomers show a CD spectrum typical of a protein in a partly folded state
with a moderate content of α-helix structure (Fig. 3.3 B, red line). The spectrum of
oligomers is shown in comparison with CD spectra of monomeric aS (Fig. 3.3 B,
continuous line) and of the mixture of aS/DHA before gel filtration (Fig. 3.3 B, dashed line,
from De Franceschi et al., JBC 2011). The loss of α-helix structure can derive from the fact
that part of DHA was removed by gel filtration step. Interestingly, further addition of DHA
to oligomers, isolated by gel filtration, induces again an increase of their α-helical
structure (Fig. 3.3 C), as observed for monomeric aS. The transition between partly folded
state and α-helix follows a two-state model, for the presence of an isodichroic point at
203 nm in the titration experiment. Since in monomeric aS is the N-terminal region the
responsible for membrane recognition and for cooperative formation of helical domains
(Bartels et al., 2010), it is reasonable to assume that in the partly folded state, the N-
aS/DHA 1:50
Wavelength (nm)200 210 220 230 240 250
[θ] x
10-3
(de
g.cm
2 .dm
ol-1
)
-25
-20
-15
-10
-5
0
0h
3h
24h
48h
Wavelength (nm)200 210 220 230 240 250
[ θ] x
10-
3 (d
eg·c
m2 ·
dmol
-1)
-30
-20
-10
0
Wavelength (nm)200 210 220 230 240 250
[θ] x
10-
3 (d
eg·c
m2 ·
dmol
-1)
-10
-8
-6
-4
-2
0
Oligomers
25 µM DHA
100 µM
250 µM
50 µM
Oligomers
aS
aS/DHA 1:50
A C B
- 56 -
terminal region or part of it is still free to drive the association of oligomers with
membranes and lipids.
Oligomers were then observed by transmission electron microscopy (TEM), atomic
force microscopy (AFM) and DLS (Fig. 3.4). These analyses provide information about an
average size distribution of the oligomers. As previously reported by De Franceschi et al.
(2011), TEM analysis shows that the chromatographic fraction corresponding to
oligomers has a spherical morphology, with diameters ranging from 12 to 35 nm. In Fig.
3.4 B the number size distribution from aS/DHA oligomers obtained by DLS analysis is
shown, indicating a mean size of 22 ± 8 nm. AFM measurement based on height
differences, shows the presence of two main populations, one is smaller (1.1 ± 0.1 nm)
and the other is larger (4.1 ± 0.1 nm). To better compare AFM and DLS results, the profile
peaks of two section containing oligomers of different size are also reported. The
diameter of smaller oligomers (Fig. 3.4 D and E, black arrows) is about 20 nm, in
agreement with the average value calculated by DLS measurements. Bigger oligomers
(Fig. 3.4 D and E, red arrows) have diameter of about 50-60 nm, values still included in the
size distribution curve obtained from DLS.
- 57 -
Diameter Size (nm)1 10 100 1000
Num
ber
0
5
10
15
20
25
100 nm
A B
7 nm
0µM
1 µM
C
E
D
Fig. 3.4. Structural characterization of aS/DHA oligomers after their isolation by gel filtration.
(A) Transmission electron microscopy and (B) DLS for particle size estimation of aS/DHA
oligomers. (C) Tapping mode AFM image of oligomers and relative XZ profile of sections indicated
by dotted line (D) and dashed line (E).
- 58 -
- 59 -
4. INTERACTION WITH MEMBRANES
4.1 Morphological analyses of liposomes
Liposomes were used to obtain membrane-mimetic systems to study oligomers
interaction with membrane. Different phospholipid composition vesicles were prepared:
DOPG, DOPG-POPE, POPS-POPC, POPC, POPE, TBE, as small unilamellar (SUV) and large
unilamellar (LUV) vesicles. Different phospholipids were tested to check aS/DHA
oligomers binding preference. Indeed, it is generally recognized that aS has a strong
preference for binding to anionic membranes (Davidson et al., 1998; Zhu & Fink, 2003),
but this information is lacking for aS/DHA oligomers. Thus, liposomes with -1, -0.5 and 0
net charge were used. Immediately after preparation, dynamic light scattering (DLS) and
electron transmission microscopy (TEM) were used to confirm the formation of liposomes
of the desired size. Liposomes were tested for their stability on time measuring the
average diameter by DLS immediately and after one week of storage at 4°C. The mean
diameter for LUV and SUV, measured immediately after extrusion, is different for all the
different phospholipid composition, as reported in Table 4.1: the smaller values were
obtained with 1POPC:1POPS and the larger with POPE. After one week of storage at 4°C,
there are no relevant differences in the average diameter, except for POPE vesicles.
Immediately after extrusion with a polycarbonate membrane with pore of 30 nm, POPE
SUV appear large as LUV. Moreover, after one week storage, the average diameter of
POPE LUV increases of about +1096.8 nm (Table 4.1). This instability is due the tendency
of phosphatidylethanolamine to self-aggregate after re-hydration and to form aggregates
and floccules. Since other phospholipidic compositions allow to obtain more stable
liposomes, POPE was not used for experiments. However, vesicles were always used
within few days after preparation. In Fig. 4.1 the three main composition, corresponding
to 100% and 50% negatively-charged phospholipids and total brain extract (with less than
40% negative charged lipids) are reported. These three conditions were used also for the
experiments as they provide, on the base of far-UV CD measurements, conditions for high
(DOPG), middle (1POPC:1POPS) and low (TBE) interaction with aS/DHA oligomers (data
reported in §4.2). Also POPC and POPE correspond to 100% zwitterionic or neutral lipids,
but the use of an extract (TBE) was preferred, compared to single-phospholipid
compositions. DLS and TEM (Fig. 4.1, inset) show comparable diameter size (average
- 60 -
Diameter Size (nm)
1 10 100 1000
Inte
nsiti
es %
0
5
10
15
Diameter Size (nm)10 100 1000 10 100 1000
DOPG SUV 1POPC:1POPS SUV TBE SUV
Radius Size (nm)
values reported in Table 4.1). From TEM is possible also to control the morphology of
liposomes: DOPG and 1POPC:1POPS have more regular distribution, and present the
typical aspect of liposomes on mica, due to the drying of the samples. TBE liposomes, that
show a larger size distribution with DLS, have also a different morphology on TEM picture,
probably due to the unknown components of the extract.
Fig. 4.1 DLS and TEM of SUV of different composition DOPG, 1POPC:1POPS AND TBE liposomes
were diluted to a final lipid concentration of 0.5 mM and observed immediately after preparation.
4.2 aS/DHA oligomers interact with membranes
Spectroscopic analyses by CD were conducted in order to study the interaction of
oligomers with vesicles. It has been reported in literature that aS adopts an α-helical
conformation induced by interactions with membranes, particularly those containing
acidic phospholipids, and also with detergent micelles. The N-terminal and NAC regions
include the imperfect repeats, xKTK(E/Q)GVxxxx, highly conserved in orthologous genes
that can adopt an amphiphilic helical structure, a classical motif for membrane-interacting
proteins. So we use this criteria to verify if oligomers are able to interact with
membranes. aS/DHA oligomers were diluted to a final concentration of 5 µM, and
analyzed by far-UV CD in the absence and in the presence of vesicles with different size
and composition. Oligomers, as previously reported, after gel filtration, have a partly α -
helix folded state (Fig. 4.4 A, red line). The CD spectra are reported in Fig. 4.2 and show
that vesicles containing negative charged phospholipids induce a structural transition of
aS/DHA oligomers in a dose dependent manner. DOPG vesicles strongly induce α-helix
structure acquisition of aS/DHA oligomers, while vesicles containing 50% of negative
- 61 -
charged lipids such as 1POPS:1POPC and 1DOPG:1POPE have less effect. POPE, POPC
(zwitterionic phospholipids) and TBE (mixture with less than 40% negative charged
phospholipids) do not induce structural transition. No significant difference was observed
using LUV and SUV with the same composition, lacking information about a membrane
curvature preference of aS/DHA oligomers.
Fig. 4.2. Far-UV CD of aS/DHA oligomers in the absence (red line) and in the presence (black lines)
of vesicles. Vesicles of different composition were used, as reported in figure. Both LUV (dashed-
dotted lines) and SUV (dotted and dashed lines) were tested.
- 62 -
4.3 Aggregation in the presence of lipids and membranes
Membrane-induced or lipid-accelerated fibril formation of amyloidogenic proteins
was frequently observed. Zhu and colleagues (2003) demonstrated that the fibrillation of
aS is very significantly affected by acidic phospholipids vesicles in a concentration-
dependent fashion. By CD spectra it was demonstrated that, at high lipid/protein ratios,
PA/PC and PG/PC vesicles induce α-helical structure in aS, whereas lower ratios of about
5:1 mass ratio of protein to lipid induce a partially folded α-synuclein intermediate (Zhu et
al., 2003). The presence of this intermediate has been previously correlated with
enhancement of formation of aS fibrils (Uversky et al.,
2001). More recently, also Reynolds and colleagues
reported that aS aggregates when applied on lipid
bilayer surface at nanomolar concentrations, causing
the extraction of lipid molecules and subsequent
membrane thinning, as represented in Fig. 4.3
(Reynolds et al., 2011). aS and A53T fibrils formation
detected in the presence of synaptosomal lipid
vesicles appeared to be associated with vesicles
suggesting a partial insertion of aS into the bilayer,
which could act as an anchor for site-directed fibril
assembly (Jo et al., 2004).
Fig. 4.3. Schematic drawing showing the proposed mechanism of membrane damage caused by
aggregation of aS on membrane. (a) Monomeric aS adsorbed to the membrane. (b) Aggregation
of aS monomers initiates membrane thinning and lipid extraction around the growing aggregates.
(c) A 24 h period of incubation results in the presence of mature aS fibrils. Subsequently,
membrane integrity is lost (from Reynolds et al., 2011).
To analyze the effect of membranes on the aggregation properties of aS/DHA
oligomers, aS and aS oligomers were incubated in the absence and in the presence of
vesicles (molar ratio protein/lipid of 1:20 and 1:50). The aggregation was conducted in
the presence of DOPG SUV, since oligomers preferentially interact with negatively
charged membranes and DHA (molar ratio protein/fatty acid 1:50), as control. The effect
of the lipids on protein aggregation was monitored by ThT fluorescence assay (Fig. 4.4).
The aggregation process of aS results sped up in the presence of DOPG SUV (1:20) (Fig.
- 63 -
4.4 A, empty circles), while in the presence of DOPG SUV (1:50) is inhibited (Fig. 4.4 A,
empty triangles). TEM analysis shows that in the mixture corresponding to aS incubation
for 9 days in the presence of SUV DOPG (1:20) there are aS amyloid-like fibrils associated
to the surface of SUV (Fig. 4.4 A, inset). The size and morphology of these fibrils are
similar to those of aS fibrils formed in the absence of SUV. In both cases, aS forms
straight, unbranched fibrils with a width of 10–15 nm. An additional feature is that the
shape of vesicles in contact with fibrils is not changed. In the presence of DHA, as
previously observed, there is not formation of aS aggregates that bind ThT dye (Fig. 4.4 A,
inverted black triangles). In the case of aS/DHA oligomers, their incubation in the
presence or the absence of SUV or DHA does not result in any increase of the
fluorescence of ThT dye (Fig. 4.4 B), confirming their nature of off-pathway intermediates
(De Franceschi et al., 2011). The aggregation process was further monitored by CD
spectroscopy, confirming the presence of
β-sheet structure only for ThT-positive
fibrils (Fig. 4.5).
Fig. 4.4. Aggregation studies monitored by
ThT assay. aS (A) and aS/DHA oligomers (B)
aggregation processes were conducted at
37°C in the presence of lipids and followed by
ThT binding assay. aS or aS oligomers were
dissolved in 20 mM Tris, 150 mM NaCl pH 7.4
at a 50 µM concentration in order to induce
aggregation, in the absence (black circles)
and in the presence of DOPG SUV, at molar
ratio 1:20 (empty circles), 1:50 (empty
triangles) and in the presence of DHA (molar
ratio 1:50, inverted black triangles). The
excitation wavelength was fixed at 440 nm,
and the fluorescence emission was collected
at 485 nm. To better visualize the
aggregation trend of aS and aS in the
presence of DOPG (molar ratio 1:20), the
data points are fitted with a sigmoidal
equation (SigmaPlot software). Inset: TEM
images of protein material relative to aS and
aS/DHA oligomers samples after 9 days of
incubation in the presence of DOPG SUV
(molar ratio 1:20).
- 64 -
Fig. 4.5. Aggregation studies monitored by far-UV CD. aS or aS oligomers were dissolved in 20
mM Tris, 150 mM NaCl pH 7.4 at a 50 μM concentration in order to induce aggregation, in the
absence (solid lines) and in the presence of DOPG SUV, at molar ratio 1:20 (dotted lines), 1:50
(dashed-dotted lines) and in the presence of DHA (molar ratio 1:50, dashed lines).
-12
-10
-8
-6
-4
-2
0
-30
-20
-10
0
aS
+ DOPG 1:20
+ DHA 1:50
aS
-20
-15
-10
-5
0
aS
+ DOPG 1:20
+ DHA 1:50
4 days
Wavelength (nm)
200 210 220 230 240 250
-25
-20
-15
-10
-5
0
aS
+ DOPG 1:20
+ DHA 1:50
9 days
+ DOPG 1:50
+ DOPG 1:50
+ DOPG 1:50
0 h
-6
-4
-2
0
aS oligomers
+ DOPG 1:20
+ DHA 1:50
aS oligomers
+ DOPG 1:20
+ DOPG 1:50
+ DHA 1:50
aS/DHA oligomers
Wavelength (nm)
200 210 220 230 240 250
-6
-4
-2
0
aS oligomers
+ DOPG 1:20
+ DHA 1:50
+ DOPG 1:50
+ DOPG 1:50
4 days
9 days
0 h
- 65 -
4.4 aS/DHA oligomers induce permeabilization of synthetic membranes
Since aS/DHA oligomers are able to interact with negative charged phospholipids,
the effect of this interaction on liposomes was investigated. A standard test to evaluate
the lipid disruption properties of oligomers is the calcein-leakage test. Fluorescence
emission of liposomes loaded with calcein is measured before and after oligomers
addition. Because of the self-quenching effect due to the high concentration of calcein in
the liposomes, the initial fluorescence emission depends only by traces of external dye.
After addition of oligomers, if the dye leaks as a consequence of altered permeabilization
of membranes, the fluorescence emission of calcein results enhanced because of the
dilution in the external environment. aS/DHA oligomers effects were measured 30 min
after their addition to different vesicles (Fig. 4.6 A) and we have tested vesicles composed
by DOPG, 1POPC:1POPS and TBE. These compositions differ for the percentage of
negative charged phospholipids: DOPG and 1POPC:1POPS, composed by 100% and 50%
negative-charged phospholipids respectively, and TBE with less than 40% negative
charged phospholipids, but the detailed composition is not available. We observed that
only DOPG liposomes were permeabilized by oligomers, while the other two tested
composition do not show significant difference between aS oligomers, monomers and
fibrils. So phospholipids that do not induced structural transition on aS oligomers are not
even destabilized by oligomers. Also in the case of 1POPC:1POPS, that induces a minor
effect on the oligomer structure (Fig. 4.2), there is no release of calcein from vesicles.
Thus, binding of oligomers to membranes not necessarily lead to membrane
permeabilization.
aS/DHA oligomers effect on DOPG liposomes were measured at different
concentration of protein species, in comparison with aS monomers, fibrils and also DHA
alone (Fig. 4.6 B). Oligomer effect is significantly different from those of other species,
since they are able to permeabilize vesicles in a dose dependent manner, while aS and
fibrils do not, even at that concentration (2.5 μM) that allows aS/DHA oligomers to cause
the maximum effect.
Since aS/DHA oligomers are able to destabilize membrane, it is important to
characterize the mechanism of action. A critical parameter to understand the type of this
destabilization is to verify the presence and eventually the dimension of a pore or
membrane aperture. Indeed calcein used for the previous study is a really small molecule
- 66 -
(622.5 Da), that gives no information about the kind of destabilization: pore formation,
transient destabilization due to oligomers insertion or even detergent effect on
membranes would be not discernible with this test. To deeper characterize oligomers
effect on membranes, first step was a supplemental leakage test performed with
fluorescein-isothyocianate-dextran loaded vesicles. Dextran, that has an average
molecular weight of 10,000 Da, could leak only if a pore/aperture of almost 4 nm occurs.
aS/DHA oligomers or aS monomers were
added to DOPG SUV and LUV (Fig. 4.5 C):
both species show no difference in inducing
leakage of Dextran, indicating a size
selection of molecule that could leak in the
presence of aS/DHA oligomers, and defining
an aperture size between 1 and 4 nm
(Mazzucca et al., 2010).
Fig. 4.6. Calcein-leakage test on liposomes. (A)
Fluorescence measurement of calcein-loaded
LUV of different composition after 30 min
incubation with monomeric aS, aS fibrils and
aS/DHA oligomers at a final concentration of 1
μM. (B) Fluorescence measurement of calcein-
loaded SUV after 30 min incubation with
increasing concentration of DHA alone,
monomeric aS, aS fibrils and aS/DHA oligomers.
Final protein concentration was 0.1, 0.5, 1 and
2.5 μM. (C) Fluorescence measurement of FITC-
dextran loaded SUV and LUV after 30 min
incubation with aS/DHA oligomers and
monomeric aS at a final concentration of 2.5
μM.
- 67 -
4.5 aS/DHA oligomers permeabilize cellular membranes
Previously, it was reported that aS/DHA oligomers are toxic to dopaminergic cells
(De Franceschi et al., 2011). To correlate this assumption with leakage test, oligomers
permeabilization activity was studied also on cells. Standard methods to analyze cells
viability or permeabilization consist in a previous phase of exposure to potential toxic
species, and then detection of effect with fluorescent dye. This approach would limit the
detectable permeabilizing effect only to a stable pore formation that will still be active
after the incubation phase. Other mechanism such as transient aperture due to oligomers
insertion, detergent effect or flip-flop temporary enhancement would not be detectable
adding dye after long time incubation. For this reason, a different method was developed:
aS/DHA oligomers, propidium iodide (PI) and Hoechst dye were added simultaneously to
cells. In this way, every single event that will cause membrane destabilization would allow
PI to enter the cells. After 30 minutes of incubation, fluorescence signal of cells
permeabilized to PI were merged with Hoechst-evidenced nuclei. aS/DHA oligomers
effect was measured in comparison with aS monomers (Fig. 4.7). Oligomers are able to
permeabilize cells, even if in a really minor extent than that exerted on liposomes. The
lower effect is due to the complexity of cells membrane toward vesicles and to the minor
content of negative-charged phospholipids that allows the higher effect on DOPG
vesicles. Moreover, aS/DHA oligomers at the same concentration (0.5 µM) are able to
induce the apoptotic death of 2.5% of cells after 24h (De Franceschi et al., 2011), a
percentage consistent with this extent of permeabilization.
Fig. 4.7. PI influx in dopaminergic cells. SH-SY5Y cells
were treated with aS/DHA oligomers and the number of
PI-positive cells was calculated as a percentage of the
total counterstained cells. Quantization (n = 3 cultures,
with 5 fields analyzed per culture, 250-300 cells per
field; error bars indicated the S.E.) indicated that
aS/DHA oligomers increased the percentage of PI-
positive cells. Statistical significance was calculated by
one-way ANOVA (p < 0.05) compared with mock control
or monomeric aS.
- 68 -
4.6 Mechanism of permeabilization of aS/DHA oligomers of membranes
Oligomers can induce permeabilization by several different mechanism (Lashuel
and Butterfield, 2013). Indeed, different kind of oligomers could exert different effect on
membrane, depending on their chemical properties. The most common mechanisms are
pore formation, flip-flop enhancement, detergent effect and transient destabilization
subsequent to oligomers insertion in the lipid bilayer or to lipid extraction caused by
aggregation on membranes. Thus, it is necessary to investigate how aS/DHA oligomers
destabilize membranes. Since several different kind of aS oligomers have been produced,
there are standard method reported in literature, used to confirm or exclude a possible
mechanism of action. In order to define the mechanism of aS/DHA oligomers, different
analysis were performed for aS/DHA oligomers and will be discussed below.
4.6.1 Detergent activity
Detergent-like effect has been reported as mechanism of toxicity on membrane
for mellitin, a lytic peptide of bee venom (Chaari et al., 2013), and for aggregated species
of IAPP that form small micelle-like protein-lipid aggregates (Sciacca et al., 2012). To
analyze this possibility for aS/DHA oligomers, TEM and DLS measurement of vesicles
before and after addition of aS/DHA oligomers were conducted, to provide information
about the morphology and average size of vesicles after treatment with oligomers (Fig.
4.8 and 4.9). Number relative size distributions of LUV and SUV change upon interaction
with oligomers, resulting in a smaller average diameter size (Fig. 4.8 A and B). Comparison
with Triton X-100 effect revealed that it was not a detergent effect, also in the
concentration of oligomers able to induce 100% of calcein release. On the contrary,
intensity relative size distributions revealed even an increment of average diameter size
of vesicles (Fig. 4.8 C and D). DLS size distribution of vesicles was measured also after
addition of monomeric aS for comparison. Moreover, also 1POPC:1POPS and TBE vesicles
were used. Data are reported in Tables 4.2, 4.2, 4.4 and 4.5. Table 4.5 summarized data
from Fig. 4.8, obtained using a final molar ratio aS/lipids of 1:20, providing information
also for vesicles of different composition. Tables 4.2, 4.3 and 4.4 relate to experiment
conducted with aS monomers and aS/DHA oligomers in a molar ratio aS/lipids 1:50. In
every case the effect induced by Triton X-100 is remarkably different from that induced
- 69 -
by the protein species. For vesicles composed of TBE or 1POPC:1POPS, the effects
induced by aS or aS/DHA oligomers are similar.
Fig. 4.8. DLS measurement of liposomes. Number (A, B) and Intensity (C, D) relative DOPG LUV (A,
C) and SUV (B, D) in the absence (solid line) and in the presence of aS/DHA oligomers (grey bars)
and Triton X-100 (black bars). aS/DHA oligomers (dotted line) size distribution is reported for
comparison.
- 70 -
In addition to measurement of size distribution of vesicles, also morphology
changes were studied, observing sample of vesicles in the absence and in the presence of
aS/DHA oligomers by TEM. The images do not show significant difference between
liposomes morphology with or without aS/DHA oligomers (Fig. 4.9), allowing to exclude a
detergent effect.
Fig. 4.9. TEM of SUV (0.5 mM) in the absence (left column) and in the presence (right column) of
aS/DHA oligomers. Vesicles with different composition were observed, from the top: DOPG,
POPS-POPC, TBE.
- oligomers + oligomers
- 71 -
Fig. 4.10. Schematic representation of PLM chambers. Cis
and Trans 2-ml chambers are separated by a 25-μm-thick
Teflon septum containing a 180-μm hole, where the lipid
bilayer is formed.
4.6.2 Pore formation
aS/DHA oligomers activity was tested also on planar lipid membrane (PLM). Lipid
bilayer was formed by drying a lipid solution of 1DOPG:1DOPE in pentane. Two 2-ml
chambers, separated by a
1DOPG:1DOPE bilayer as
represented in Fig. 4.10, were filled
with 100 mM KCl, 5 mM HEPES pH
7.00 buffer. After application of
current, aS/DHA oligomers were
added to the buffer and current
alterations were measured on real time. Results show that oligomers induce alteration in
the permeability of membrane bilayer to ions, but preferentially in a unstructured
manner (Fig. 4.11). About 50% of the cases give weak activity (about 10 pA). Remaining
experiments show in the same frequency a stronger (hundreds of pA) or absence of
activity. In 25% of the experiments formation of a stable channel was observed, from few
seconds to minutes. Relative conductance was not ohmic, as major conductance was
recorded with application of negative tension. Rarely, other behaviours were observed, as
flickering of single channel or opening of
several consecutive channels. As a control, also
monomeric aS and DHA alone were tested. The
fatty acid addition does not induces any
membrane perturbation, while aS causes
formation of structured channel, as reported in
literature (Tosatto et al., 2012).
Fig. 4.11. PLM experiments. Electrophysiological
activity of aS/DHA oligomers on 1DOPG:1DOPE
lipid membranes. Buffer composition was KCl 100
mM, Hepes 5 mM, pH 7.0. Protein concentration
was 68 nM. Applied potential +80 mV (A) or +100
mV (B).
- 72 -
Table 4.1. LUV and SUV stability on time.
a Average diameters obtained from two DLS measurements of freshly prepared
vesicles solutions. b
Average diameters obtained from two DLS measurements of vesicles solutions
stored for one week at +4°C. c Difference between mean diameters of freshly prepared and stored vesicles.
d Net charge of relative phospholipids.
LUV
composition
Diameter
(nm)a
Diameter1w
(nm)b
Δ diameter
(nm)c
DOPG 370.1 417.6 +47.5
DOPG-POPE 372.3 367.7 -4.6
POPC 135.5 150.5 +15.5
POPS-POPC 289.8 303.3 +13.5
POPE 578.7 1684.5 +1096.8
TBE 381.5 376.3 -5.4
SUV
composition
Diameter
(nm)a
Diameter1w
(nm)b
Δ diameter
(nm)c
DOPG 108.2 118.7 +10.7
DOPG-POPE 112.9 156.9 +44
POPC 108.1 99.4 -8.7
POPS-POPC 99.6 102.1 +2.5
POPE 526.2 506.6 -19.4
TBE 170.4 162.2 -8.2
- 73 -
Table 4.2. Diameter size (nm) of DOPG LUV and SUV in the absence and in the presence
of monomeric aS and aS/DHA oligomers in a molar ratio protein/phospholipids of 1:50
and in the presence of Triton X-100 (0.1%) Measured were performed immediately after
aS addition and after 30 minutes and 1 hour. Values are the mean average of two
different measures.
a Relative number of particles, multiplied for their light scattering intensity
b Relative number of particles, multiplied for their volume.
c Relative number of particles of defined size.
Composition Intensitya Volume
b Number
c
LUV DOPG 355.3 ± 22.1 441.3 ± 55.6 195.9 ± 76.5
oligomers 94.72
510.2 ± 77.6
87.10
567.6 ± 94.6
77.29
426.65 ± 50.4
oligomers, 30
min 435.2 ± 107.8 450.4 ± 116.1 416.1 ± 97.2
oligomers, 1 h 397.4 ± 36.3 413.9 ± 38.2 375.8 ± 34.1
aS 81.82
357.2 ± 12.9
75.14
431.7 ± 31.2
97.33 ± 43.09
306.6
aS, 30 min 336.3 ± 10.2 369.25 ± 6.0 294.9 ± 16.3
aS, 1h 339.9 ± 37.5 448.2 ± 81.8 88.2 ± 72.5
Triton X-100 11.4 ± 1
68.0 ± 7.9 9.1 ± 0.5 7.6 ± 0.3
SUV DOPG 118.7 ± 8.6 96.2 ± 1.5 69.1 ± 12.4
oligomers 218.6 ± 21.5 58.6 ± 0.6
295.1 ± 51.4 45.04 ± 2.3
oligomers, 30
min
33.7
204.0 ± 12.6
36.3 ± 5.7
268.5 ± 21.8 29.26 ± 2.3
oligomers, 1h 31.8
205.3 ± 11.0
27.8
218.2 ± 15.9
24.6
126.3 ± 15.7
+aS 101.9 ± 1.7 65.1 ± 1.3 41.7 ± 1.7
aS, 30 min 95.5 ± 1.2 17.9
67.5 ± 3.1
17.4
47.4 ± 2.6
aS, 1h 77.9 ± 1.6 59.5 ± 3.3 47.2 ± 4.7
Triton X-100 16.0 ± 0.1
272.3 ± 85.1 11.2 ± 0.01 8.9 ± 0.05
- 74 -
Table 4.3. Diameter size (nm) of 1POPS:1POPC LUV and SUV in the absence and in the
presence of monomeric aS and aS/DHA oligomers in a molar ratio protein/phospholipids
of 1:50 and in the presence of Triton X-100 (0.1%). Measured were performed
immediately after aS addition and after 30 minutes and 1 hour. Values are the mean
average of two different measures.
Composition Intensitya Volume
b Number
c
LUV POPS-POPC 352.6 ±3.7 373.5 ±3.2 326.4 ±3.1
oligomers 56.6 ±7.7
398.4 ±21.7
51.05 ±5.8
460.9 ±34.8
45.8 ±3.9
314.5 ±1.5
oligomers, 30
min 308.7 ±10.2 322.7 ±10.0 293.2 ±9.6
oligomers, 1h 376.0 ±7.3 419.3 ±7.2 319.25 ±7.4
aS 329.8 ±31.4 360.8 ±38.9 290.15 ±19.9
aS, 30 min 304.4 ±5.2 312.8 ±5.3 296.5 ± 4.7
aS, 1h 86.6 ±12.4
428.7 ±5.9
80.40 ±13.6
481.25 ±9.7
72.26 ±12.6
355.1 ±10.0
Triton X-100 11.7 ±0.8
201.5 ±43.5 9.8 ±1.1 8.5 ±1.2
SUV POPS-POPC 33.9
163.5 ±5.4
31.6
120.3 ±43.2 40.8 ±16.6
oligomers 131.3 ±6.5 33.0
94.2 ±16.0 32.7 ±4.3
oligomers, 30
min 116.6 ±6.0 86.1 ±5.8 56.0 ± 1.9
oligomers, 1h 118.4 ±2.2 96.2 ±2.8 68.7 ±6.8
aS 156.1 ±6.9 138.4 ±8.4 78.07 ±0.3
aS, 30 min 110.4 ±8.7 75.7 ±4.9 49.19 ±0.5
aS, 1h 94.2 ±1.6 73.2 ±2.4 55.91 ±4.5
Triton X-100 9.1 ±1.40 8.0 ±0.9 7.22 ±0.6
a ,b, c see reference table 4.2.
- 75 -
Table 4.4. Diameter size (nm) of TBE LUV and SUV in the absence and in the presence of
monomeric aS and aS/DHA oligomers in a molar ratio protein/phospholipids of 1:50 and
in the presence of Triton X-100 (0.1%) Measured were performed immediately after aS
addition and after 30 minutes and 1 hour. Values are the mean average of two different
measures.
Composition Intensitya Volume
b Number
c
LUV TBE 418.8 ±34.1 432.8 ±35.8 401.9 ±33.4
oligomers 423.3 ±44.5 506.2 ±81.3 314.8 ±0.5
oligomers, 30
min
77.2
456.2 ±1.62
70.8
549.8 ±9.1
63.4
326.9 ±2.1
oligomers, 1h 397.3 ±14.1 438.1 ±15.3 343.5 ±11.6
aS 444.7 ±10.5 478 ±17.2 398.7 ±0.6
aS, 30 min 410.6 ±3.1 454.95 12.1 351.75 ±8.1
aS, 1h 426.25 ±34.0 439.2 ± 37.3 411.1 ±30.7
Triton X-100 5.0
224.7 ±7.4
4.8
239.2
4.7
220
SUV TBE 220.4 16.6 74.9
262.5 ±58.2 114.9 ±75.4
oligomers 49.9
209.1 ±16.6
52.4 ±9.8
243.4 ±52.7 45.1 ±5.3
oligomers, 30
min 193.8 ± 14.9
92.3 ± 27.6
299.4 ±0.8 70.2 ±22.4
oligomers, 1h 32.5
151.7 ±3.2
29.7
134.05 ±0.9
27.6
83.5 ±7.4
aS 213.3 ±21.1 88.9
286.3 ±110.0 103.6 ±55.5
aS, 30 min 55.0
196.9 ±9.7
50.7 ±3.1
206.3 ±13.1 50.5 ±2.7
aS, 1h 36.8
197.3 ±7.3
42.1 ±12.6
203.4 ±7.3
43.0 ±17.8
104.6
Triton X-100 6.8 ±0.5
92.2 ±10.7 6.0 5.8 ±0.3
a ,b, c
see reference table 4.2.
- 76 -
Table 4.5. Diameter size (nm) of different composition LUV and SUV in the absence and in
the presence of monomeric aS and aS/DHA oligomers in a molar ratio
protein/phospholipids of 1:20 and in the presence of Triton X-100 (0.1%). Measurements
were performed after 30 minutes.
a ,b, c see reference Table 4.2.
Composition Intensitya Volume
b Number
c
LUV DOPG 301.1 ±16.6 326.5 ±21.2 269.0 ±9.8
oligomers 42.9 ±1.0 40.9 ±1.3 38.9 ±1.4
oligomers, 30 min 109.65 ±36.7 98.355 ±33.7 89.61 ±35.3
Triton X-100 10.5 ±0.6 9.1 ±0.4 8.13 ±0.3
SUV DOPG 170.5 ±3.1 51.0 ±0.5 82.9 ±7.9
oligomers 203.5 ±6.6 214.9 ± 10.2 160.2 ± 4.4
oligomers, 30 min 27.2 ±11.4 24.95 ±8.6 22.06 ±7.7
Triton X-100 8.9 ±0.3 8.1 ±0.1 7.47 ±0.1
LUV POPS-POPC 92.9 86.2 ±0.8 78.21 ±7.8
oligomers 68.2 ±19.4 58.9 ±16.2 50.7 ±12.9
oligomers, 30 min 43.2 ±5.3 41.3 ±4.8 39.3 ±4.2
Triton X-100 9.0 ±0.3 8.29 ±0.03 7.6 ±0.2
SUV POPS-POPC 95.7 ±5.3 69.08 ±0.02 50.1 ±2.9
oligomers 138.6 ±4.0 107.5 ±16.9 44.6 ±42.5
oligomers, 30 min 144.0 ±10.5 63.9 ±6.2 31.7 ±1.1
Triton X-100 11.4 ±1.0 8.8 ±0.4 7.3 ±0.1
LUV TBE 356.3 ±4.9 375.25 ±4.0 331.6 ± 5.8
oligomers 345.5 ±41.3 366.85 ±47.4 318.4 ±31.5
oligomers, 30 min 348.9 ±43.1 418.8 ±42.9 238.8 ±63.1
Triton X-100 8.5 ±0.4 8.1 ±0.3 7.6 ±0.2
SUV TBE 219.8 ±3.4 84.95 ±3.9 55.7 ±8.6
oligomers 137 ±2.1 104.3 ±5.1 43.9 ±23.9
oligomers, 30 min 168.8 ± 22.6 104.5 ±31.5 60.1 ±7.9
Triton X-100 9.4 ±1.1 8.1 ±0.4 7.2 ±0.01
- 79 -
5. CHEMICAL MODIFICATIONS ON aS/DHA OLIGOMERS
5.1 DHA induces oxidative modifications on aS
In aS aggregates formed in the presence of DHA several oxidative modifications
were found, in terms of oxidation of Met residues, covalent addition of allylic radical
(+326 Da) and hydroperoxide radical (+358 Da) of DHA (De Franceschi et al., 2011) and
the presence of carbonyl groups that should result from the reaction of Lys, Pro or Thr
with reactive oxygen species (ROS) or from the reaction of Lys and His with lipid
peroxidation products (Thakur and Nehru, 2013). An important goal would be to obtain a
complete chemical characterization of the oxidative modifications in aS aggregates by
both the identification of modified residue(s) and the evaluation of the extent and the
randomness of these several modifications. This study would be of utmost importance to
understand the role of lipid peroxidation in oligomers formation in synucleinopathies.
The first type of modification is due to the presence of four Met residues, in
position 1, 5, 116 and 127 in the aS sequence. Met residues are easily oxidized to
methionine sulfoxide by ROS, but generally these residues are particularly susceptible to
undergo oxidation even under acid conditions in the presence of oxygen. Mass
spectrometry analysis shows aS containing from 1 (+16 Da), 2 (+32 Da), 3 (+48 Da) to 4
(+64 Da) oxidations. Both monomer and oligomer contain this pattern of Met oxidation
and the corresponding RP-HPLC peaks are almost resolved. This type of modification is
not easy to control, so it is difficult to say whether it has a role in oligomerization or the
activity of the oligomers.
The presence of other chemical modifications was investigated. To this aim the
derivatization of modified aS with dinitrophenylhidrazine (DNPH) coupled with MS
analysis was tried. DNPH reacts with carbonyls groups that form in the lateral side chain
of specific amino acidic residues (lysine, proline, arginine, and threonine) in oxidative
conditions as represented in Fig. 5.1 (Linares et al., 2011).
Fig. 5.1. Schematic representation of reaction of DNPH on carbonyls of lateral chain of
aminoacidic residues.
- 80 -
The idea is to distinguish carbonyl contributions derived from reactions of Lys, Pro, Thr
with ROS (Δmass from 0/-1 to +180) and from addition of allylic or hydroperoxide radicals
of DHA. To this aim aS/DHA mixture corresponding to 24-hr of incubation was purified by
RP-HPLC and the fraction relative to oligomers (RT of 29.5 min, Fig. 1.1) was collected and
dried. This species was incubated in the presence of DNPH, to allow the reaction with
carbonyls. Exceeding DNPH was washed with ethanol-ethylacetate extraction and UV
absorbance was measured. The same reaction was conducted on monomeric form of aS.
In Fig. 5.2 the UV-vis spectra of aS and aS/DHA oligomers reacted with DNPH were shown
in comparison with spectra of the same species not reacted. All species absorbe at 280
nm, but only oligomers show a specific UV signal at wavelength 366 nm. This wavelength
corresponds to the maximum DNPH absorbance, indicating the presence of an increased
amount of carbonyl in oligomers. DNPH labelled-proteins were analyzed by RP-HPLC,
monitoring the chromatogram at 226 nm and 366 nm. It was possible to detect the
presence of protein and the protein reacted with the fluorescent dye. The chromatogram
relative to the analysis of aS does not show any peaks at 366 nm (Fig. 5.3 B), while for
aS/DHA oligomers a peak co-eluting with oligomers at 29.5 min is detectable (Fig. 5.3 D).
This result shows that carbonyls are present in the oligomeric form of aggregated aS, but
non in the monomeric protein. The peak at 366 nm is visible just upon 1 hr incubation
(data not shown). This provides an important conclusion: the carbonylation is an early
event, being within 1 hr of incubation of aS with DHA. We can speculate that the
presence of DHA enhances the oxidative stress on aS as a consequence of its suggested
physiological function, as inhibitor of lipid oxidation (Zhu et al., 2006).
- 81 -
Fig. 5.2. UV-Vis spectra. (A) aS and (B) aS/DHA oligomers spectra of protein before (black lines)
and after (red lines) reactions with DNPH. Spectra were recorded in PBS pH 7.4.
Fig. 5.3. RP-HPLC analyses. aS in the absence (A,B) and in the presence (C,D) of DHA was analysed
by RP-HPLC before (A,C) and after (B,D) reaction with DNPH. Samples were eluted with a gradient
of acetonitrile and 0.085% TFA and elution was followed at 226 nm (black line) and 366 nm (red
line) to detect protein reacted with DNPH.
- 82 -
We made a tentative to identify the amino acid residue(s) modified by
carbonylation. We used a standard approach consisting in subjecting the protein samples
to proteolysis by trypsin and derivatizing the peptides with DNPH (Fig. 5.4). Unfortunately
by this procedure only a fragment containing the Δ mass of 180 Da was found and it
corresponds to the sequence 24-32. This peptide contains a Lys residue in position 32 and
this could be a possible target of carbonylation. However the presence of a single
modification does not justify the signals obtained in UV and RP-HPLC analyses. It could be
happen that some peptides can be lost in the extraction step of DNPH being too small and
hydrophobic. Moreover the oligomeric species is quite resistant to proteolysis and the
yield in peptide is very low. Finally it is reasonable that residues in the protein are
randomly modified and so it is difficult to detect them.
Fig. 5.4. RP-HPLC analyses of proteolysis. aS/DHA oligomers proteolyzed with Tripsin and
derivatized with DNPH was analyzed by RP-HPLC. Samples were eluted with a gradient of
acetonitrile and 0.085% TFA and elution was followed at 226 nm (black line) and 366 nm (red line)
to detect fragments containing DNPH.
- 83 -
5.2 Detection of DHA covalent adduct on aS
Mass spectrometry analysis has revealed the presence of a covalent adduct on aS
oligomers formed in the presence of DHA (De Franceschi et al., 2011). A series of signals
with a mass increase of 326 and 358 Da was observed. These mass differences are
consistent with the covalent modification of the protein for the addition of allylic radical
of DHA (326 Da) and hydroperoxide radical (358 Da), the earlier products of DHA
autoxidation. In order to identify the site(s) of modification on aS, a proteolysis followed
by mass spectrometry analysis was performed. aS/DHA oligomers were purified by RP-
HPLC (cfr. Fig. 1.1 B) after 3 hours of aS incubation in the presence of DHA (P/DHA 1:50).
HPLC fractions at 29.5 min of retention time containing oligomers were collected then
digested with trypsin for 3 hr, using an enzyme to substrate ratio of 1:100. Proteolytic
fragments were analyzed in RP-HPLC (Fig. 5.5). Mass spectrometry identification were
performed for all eluted peaks, to find DHA-adduct containing fragments (Table 5.1). In
the chromatogram several peaks are detectable. Found fragments span all aS sequence.
Met-containing peptides are present also in oxidized form (+16 Da) as previously
observed. Fragments corresponding to sequence 1-80, 1-60, 35-80, 46-80 and 46-58 were
found with a mass increase of 326 Da (Fig. 5.5). The residue that reasonably is modified is
His in position 50. Another possible site of modification would be Lys58, but we can
exclude it since if Lys58 were modified, it wouldn’t be recognized by trypsin. The peptides
containing the Δ mass of 326 Da are 1-60 (6475.2 Da), 35-80 (4923.2 Da), 46-80 (3760.9
Da) and 46-58 (1621.5 Da). There are two aspects of particular interest to evidence in this
analysis. One is the degree of modification. In fact, the modified peptide constitutes
about 2-3% of the unmodified one, making very challenging its identification. Moreover
ms-ms analysis on double-charged ions relative to modified peptides causes the removal
of the covalent adduct, also using very low collision energy. Ms-ms analysis of double
charged ion at m/z 811 relative to peptide 46-58 +326 Da forms again the peptide 46-58
without the modification, while the analysis of the double charged ion at m/z 648 give
rise to a ms-ms spectrum of peptide 46-58 (Fig. 5.6). The same behaviour was observed
for other DHA-modified peptides. In the light of these considerations and overlapping the
sequences (Fig. 5.7) of the indentified peptides we concluded that the modification is
located on His50.
- 84 -
Fig. 5.5. RP-HPLC analysis. A. Chromatogram of the proteolysis mixture of aS/DHA oligomers with
trypsin before (black lines) and after (red lines) reaction. Proteolysis was conduced in PBS pH 7.4
buffer with a E:S ratio 1:100 (by weight). B. Detail of the chromatogram from 10 to 30 min to
better see the identified fractions Numbers close the peak indicate the fragments identified by
mass spectrometry. Peaks relative to species containing DHA adduct are labelled in red.
- 85 -
Fig. 5.6. MS-MS of peptide 46-58. MS-MS analysis of peptide 46-58 of aS, eluted from RP-HPLC
results in the whole fragmentation of the fragment (top). MS-MS analysis of peptide 46-58
modified by DHA (bottom) was performed in order to detct the precise residue modified by DHA.
Spectrum reveals that the adduct dissociate and formation of unmodified 46-58 fragment occurs.
1 35 46 58 60 80
MDVFMKGLSKAKEGVVAAAEKTKQGVAEAAGKTKEGVLYVGSKTKEGVVHGVATVAEKTK
EGVLYVGSKTKEGVVHGVATVAEKTKEQVTNVGGAVVTGVTAVAQK
EGVVHGVATVAEKTKEQVTNVGGAVVTGVTAVAQK
EGVVHGVATVAEK
Fig. 5.7. Sequences of peptides characterized by a Δ mass of 326 Da. The hypothesised His 50 as
site of modification is highlighted.
- 86 -
5.3 Role of His50 in oligomerization
Histidine and lysine are nucleophilic amino acids and therefore vulnerable to
modification by lipid peroxidation derived electrophiles, such as 2-alkenals, 4-hydroxy-2-
alkenals, and ketoaldehydes, derived from lipid peroxidation. Histidine shows also a
specific reactivity toward 2-alkenals and 4-hydroxy-2-alkenals, whereas lysine is a
ubiquitous target of aldehydes, generating various types of adducts (Uchida, 2003).
Covalent binding of reactive aldehydes to histidine and lysine is associated with the
appearance of carbonyls and antigenecity of proteins. In our case His50 is resulted the
most frequent site of formation of an adduct with DHA. It is of great interest after that to
investigate the importance of the position of the DHA adduct for aS oligomerization. To
this aim we have studied a mutant of aS containing in position 50 a glutamine residue
(H50Q). Moreover this species is naturally occurring mutant, found in familiar form of PD
(Proukakis et al., 2013). The protein was obtained by recombinant technique and it was
characterized by mass spectrometry, after purification by RP-HPLC (Fig 5.8).
Fig. 5.8. (A) RP-HPLC of H50Q after purification by ion exchange and (B, C) MS spectra of the
major fraction. Further details are described in Methods section.
To investigate the influence of H50Q variant on the interaction with DHA, far-UV
CD measurement were performed (Fig. 5.9), in the presence of increasing amount of
DHA. In comparison with aS, H50Q shows a similar extent of acquisition of a-helical
A
B
C
- 87 -
structure. To further investigate the possible occuring differences, aS and H50Q were
proteolyzed with pK in the presence of saturating amount of the FA. After 5 min of
reaction, the first fragments were detectable. RP-HPLC and mass spectrometry analysis
(Fig. 5.10) (Table 5.2) of obtained species reveal that the same cleavage sites were
present in the two protein, suggesting a really similar interaction mode of aS and H50Q.
Wavelength (nm)
200 210 220 230 240 250
H50Q
200 210 220 230 240
[θ] x
10-
3 (d
eg. c
m2 .
dmol
-1)
-30
-20
-10
0
1:25
1:50
1:60
1:801:70
1:25
1:501:60
1:801:70
aS
Fig. 5.9. CD measurements. Far-UV CD spectra of aS and H50Q in the absence and in the presence
of DHA at different molar ratio. Spectra were recorded in PBS pH 7.4, at a protein concentration
of 5 µM, and in the absence or in the presence of DHA in a final molar ratio protein:lipid of 1:25,
1:50, 1:60, 1:70 and 1:80.
Fig. 5.10. RP-HPLC chromatograms of the proteolytic mixture of aS and H50Q with pK in the
presence of DHA with a molar ration protein:lipid 1:70, after 5 min of incubation. Proteolysis were
conducted with proteinase K in a E:S ratio of 1:1000. The fractions are collected and analyzed by
mass spectrometry to identify the peaks.
- 88 -
Retention Time (min)10 15 20 25 30 35
Retention Time (min)10 15 20 25 30 35
Rel
ativ
e A
bsor
banc
e at
214
nm
H50Q aS
0h
3h
24h
48h
0h
3h
24h
48h
H50Q was incubated with DHA under the same conditions used to obtain aS/DHA
oligomers and its aggregation process was monitored by GF (Fig. 5.11) and RP-HPLC (Fig.
5.12). The aggregation process of H50Q in the presence of DHA shows a comparable
extent of oligomerization. The retention volume of oligomers is the same for the two
species, meaning that they have the same hydrodynamic volume.
Fig. 5.11. Gel filtration analysis. Chromatograms of the mixtures of H50Q (left) and aS (right)
with DHA in a molar ratio 1:50 during aggregation. The number on the left refers to the time of
incubation.
The mixture of H50Q in the presence of DHA was also analyzed by RP-HPLC (Fig. 5.10 and
Table 5.3) and the behaviour of oligomers compared to aS. The patterns are quite similar
and just after 3 hours H50Q oligomers form with similar RT of 29.5 min, indicative of very
hydrophobic species. Moreover after 48 hours most of the monomeric protein is
converted in oligomer.
- 89 -
1015
2025
3035
Time (h
rs)
Retention Time (min)
1015
2025
3035
Time (h
rs)
Retention Time (min)
0
3
24
48
0
3
24
48
Fig. 5.12. RP-HPLC analysis. Chromatograms of H50Q (A) or aS WT (B) in the presence of DHA in a
molar ratio 1:50 during aggregation. The colour indicate the time of incubation: 0 (red), 3-
(orange), 24- (yellow) and 48- (green) hours.
The most important feature of H50Q oligomers to compare to aS ones is the
presence, and eventually the position, of DHA adducts. For this reason, H50Q/DHA
oligomers were purified by RP-HPLC and analyzed by mass spectrometry (Fig. 5.13).
Analysis showed that DHA still binds to the protein and moreover more than one DHA
adduct was present on single protein molecules. As done for aS, proteolysis experiments
were conducted in order to identify possible favourite sites of modification.
- 90 -
Fig. 5.13. Mass spectrometry analysis. Mass spectrum of H50Q/DHA oligomers purified by RP-
HPLC after 3 hours incubation.
Proteolysis was conducted using trypsin, in a E:S ratio 1:100 by weight. Proteolytic
solutions were analyzed in RP-HPLC after 30 min (Fig. 5.14). Mass spectrometry
identification were performed for all eluted peaks, to find DHA-adduct containing
fragments (Table 5.4). We identify the same peptides as aS, and those containing Q50
show the correct mass decrease of 9 Da due to substitution of His with Gln (table 5.4).
Since His50 had been removed, different modified fragments were sought. We were not
able to find modified peptides. This means that probably a favoured site for modification
is absent and this leads to spread DHA between the several lysine present on the protein.
As a consequence, a single specific lysine is rarely modified, thus it is not detectable with
this kind of analysis.
To further characterize H50Q/DHA oligomers, their ability to affect synthetic
membranes was tested. As already done for aS (§ 3.6), calcein test was used. DOPG LUV
loaded with calcein were treated with 1 µM solution of H50Q oligomers (Fig. 5.15).
Oligomers show to be able to destabilize vesicles at the same extent of aS oligomers.
- 91 -
Fig. 5.14. RP-HPLC analysis. Chromatogram of H50Q/DHA oligomers after 30 minutes of
proteolysis with trypsin. Proteolysis was conducted in PBS pH 7.4 buffer at 37°C with a E:S ratio
1:100 (by weight).
Fig. 5.15. Calcein-leakage test for H50Q/DHA oligomers. Fluorescence measurement of calcein-
loaded DOPG LUV after 30 min incubation with oligomers of H50Q or aS formed in the presence
of DHA 1:50.
This result allows us to deduce that the specific position of the modification in aS
sequence by DHA is not essential for oligomers formation and activity. Considering that
we never obtained unmodified oligomers, we can not exclude a role of this adduct
considering that it not possible to obtain oligomers without modification.
- 92 -
Table 5.1. Chemical characterization of fragments corresponding to mayor peaks of the
chromatogram relative to the fragmentation of aS/DHA oligomers with trypsin after 3 hr
of incubation.
Molecular Mass (Da) RTa
(min) Foundb Calculated
c
Peptide
speciesd
11.2 830.43 829.91 24-32
13.2
1524.16±0.01
1294.99±0.05
1294.8±0.1
1754.37±0.02
1523.74
1294.68
1621.46
1754.02
44-58
46-58
46-58+326
44-60
13.8 1406.9±0.1
1179.93±0.05
1409.65
1180.37
33-45
35-45
14.1 950.7±0.01 951.09 35-43
14.7 2157.17±0.04 2157.45 59-80
14.9 1607.16±0.01 1606.84 81-97
15.1 2148.14±0.11 2148.44 81-102
15.4 1928.41±0.05 1928.17 61-80
15.6 1478.05±0.04
4923.6±0.13
1478.66
4923.25
81-96
35-80 +326
17.9 4847.06±0.38
6472.55±0.75
4846.03
6475.19
98-140+1ox
1-60+326
19.3 4958.66±0.01 4958.20 97-140
19.9 4288.74±0.34
4830.5±0.1
4288.43
4830.03
103-140
98-140
21.2 6434.93±0.04
6451.22±0.46
6434.86
6450.86
81-140+1ox
81-140+2ox
23.4 6418.65±0.13 6418.86 81-140
28.2
3434.52±0.05
3760.8±0.05
3664.32±0.01
3434.89
3760.89
3664.18
46-80
46-80+326
44-80
a Peptides or proteins were purified by RP-HPLC and listed in order of
retention times (RT). b
Experimental molecular masses determined by ESI-MS. c Molecular masses calculated from the amino acid sequence of aS.
d Species containing Met residues are present also as oxidized form.
- 93 -
Table 5.2. Chemical characterization of peptide material corresponding to mayor peaks of
the chromatograms relative to the fragmentation of aS and H50Q bound to DHA with
proteinase K after 5 min of incubation.
a ,b, c, d see reference Table 5.1
Table 5.3. Chemical characterization of protein material corresponding to mayor peaks of
the chromatogram relative to the aggregation of aS and H50Q in the presence of DHA.
Molecular Mass (Da) RTa
(min) Foundb Theoretical
c
Speciesd
14508.13 ±0.05 14508.1 aS 3ox 19.5
14491.8 ±0.5 14492.1 aS 2ox
21 14459.92 ±0.01 14460.1 aS
14817.1 ±0.7 14818.1 aS 2ox 326 31.5
14831.3 ±0.9 14834.1 aS 3ox 326
14522.4±1.1 14522.2 H50Q 2ox
17.8 14554.6 ±0.2 14554.2 H50Q 4ox
18.5 14506.3 ±0.6 14506.2 H50Q 1ox
18.9 14490.5 ±0.3 14490.2 H50Q
31.5 14824.0±1.13 14825.2 H50Q 3ox 326 e32 326.28 ±0.08 326.24 DHA (-2H)
33 328.29 ±0.16 328.24 DHA a ,b, c, d
see reference Table 5.1 e Peaks eluted at 32 and 33 min correspond to DHA for all analyzed protein.
Molecular Mass (Da) RTa
(min) Foundb Theoretical
c
Speciesd
18.4
5633.10±0.11
5390.01±0.11
5633.0
5389.7
90-140
93-140
29.7 7174.57±0.06 7173.7 73-140
30.1 8846.32±0.74 8845.2 1-89
30.4 9088.98±0.59 9088.5 1-92
30.8 14477.41±0.4 14476 1-140+1ox
31.5 14460.05±0.27 14460 1-140
18.4
5633.14±0.12
5389.77±0.48
5633.0
5389.7
90-140
93-140
29.6 8837.24±0.36 8836.2 1-89
29.9 9079.42±0.42 9079.45 1-92
30.4 14452.58±0.40 14451.2 1-140
aS
H50Q
H50Q
aS
- 94 -
Table 5.4. Chemical characterization of peptide material corresponding to mayor peaks of
the chromatograms relative to the fragmentation of H50Q/DHA oligomers with trypsin
after 30 min of incubation.
Molecular Mass (Da) RTa
(min) Foundb Calculated
c
Speciesd
11.3 829.42
1058.59
829.43
1058.57
24-32
22-32/24-34
12.5
1071.6
872.47
1300.78
1071.59
872.46
1300.74
11-21
13-21
11-23
12.7 1101.63 1101.60 13-23
13.2 801.37 801.35 1-6 2ox
13.7 1179.74
1285.66
1179.65
1285.69
35-45/33-43
46-58
13.9 1744.10 1743.97 44-60
14.1 950.56
785.39
950.51
769.35
35-43
1-6 1ox
14.3
1514.97
1170.68
950.5
1688.82
1285.78
1514.83
1170.58
950.51
1685.97
1285.69
46-60
1-10 1ox
35-43
7-23
46-58
14.7 1605.98 1605.87 81-97
15.1 1910.64±0.46
2157.36
1927.04
2156.18
61-80
59-80
15.5 4862.2
1477.3
4862.03
1478.7
98-140 2ox
81-96
17.1 4972.99±1.57 4974.20 97-140 1ox
18.9 4958.46±0.03 4958.20 97-140
19.4 4288.07±0.39
4829.38±0.75
4288.43
4830.03
103-140
98-140
22.8 6418.11±0.51 6418.86 81-140
29.1
3655.36±0.07
4819.30±0.19
5629.74
3655.17
4817.52
5629.41
44-80
33-80
24-80
29.4 3425.1 3423.80 46-80 a ,b, c, d
see reference Table 5.1
- 95 -
6. aS FAMILIAR VARIANTS AND DHA
Genetic studies of the aS gene in familial cases of PD have demonstrated that
overexpression of normal aS is associated with this disease. However also pathogenic
missense mutations, A53T (Polymeropoulos et al., 1997), A30P (Kruger et al., 1998), and
E46K (Zarranz et al., 2004) and multiplication (Chartier-Harlin et al., 2004; Farrer et al.,
2004; Fuchs et al., 2007; Singleton et al., 2003) of the aS gene have been identified in
kindreds of autosomal dominantly inherited familial PD and DLB (Fig. 6.1). Recently other
missense mutations have been found, such as H50Q (Proukakis et al., 2013) and G51D
(Kiely et al, 2013).
1 10 20 30 40 50 60
MDVFMKGLSK AKEGVVAAAE KTKQGVAEAA GKTKEGVLYV GSKTKEGVVH GVATVAEKTK
P K Q D T 70 80 90 100 110 120
EQVTNVGGAV VTGVTAVAQK TVEGAGSIAA ATGFVKKDQL GKNEEGAPQE GILEDMPVDP 130 140
DNEAYEMPSE EGYQDYEPEA
Fig. 6.1. Schematic representation of the localization of main aS mutations.
It is not yet fully clear how these mutations affect the pathogenesis of PD. It is seems that
E46K mutation produces aS peptides displaying an increased propensity to form relatively
large oligomers, whereas the A30P mutation produces aS peptides displaying decelerated
secondary structure transitions and a decreased propensity to form oligomers (Ono et al.,
2011). Another aspect concerns the ability of aS mutants to bind phospholipids and fatty
acids. The mutant A30P is defective in binding to phospholipid vesicles, while the A53T
substitution displays a normal membrane-binding activity, comparable to wild-type aS (Jo
et al., 2002). Bodner and coll. (2010) have reported the phospholipid binding properties
of the variants, viewed by solution NMR. They show overall decreased lipid affinity for the
A30P mutation, comparable affinity for A53T, and an increased level of binding of E46K,
relative to wild-type aS.
We investigated the ability of a group of aS mutants to bind DHA by circular dichroism
and proteolysis experiments. Further we have evaluated the propensity of these protein
species to oligomerize in the presence of DHA. This study could help to get more
- 96 -
information about the interaction between aS and fatty acids and the role of this
interaction in the pathogenesis of PD.
Fig. 6.2. Scheme depicting the increased vulnerability of aS to self-association when engaged in
the SL1 binding mode vs SL1. SL1 and SL2 refer to two different bound state to phospholipids: SL1
comprise a short bound α-helix followed by dynamic disordered residues ~25-140; SL2 engages
the full N-terminal domain, up to residue ~100, in the α-helical conformation, while the 40
residues of the C-terminal tail remain flexible in solution. All variants increase the relative
population of SL1, for which a long unstructured stretch of N-terminal residues is exposed
(reprinted from Bodner et al., 2010).
6.1. Conformational analysis.
The secondary structure of A30P, A53T and E46K in the presence of DHA was
analyzed by far UV circular dichroism (CD). All mutants are unfolded in solution while
increasing the amount of DHA, the appearance of the two typical minima at 2008 and 222
nm is observed, indicating the acquisition of α-helical secondary structure (Fig. 6.3).
The overall behaviour of the proteins is similar and they show a similar susceptibility to
acquire α-helix conformation upon addition of the fatty acid. The presence of an
isodichroic point at 203 nm in the titration experiments suggest a two state transition
from random coil to α-helix. To further analyze the interaction the ellipticity was shown as
a function of the molar ratio between the proteins and DHA. Especially the ellipticity at
208 nm or the ratio between the ellipticity at 208 in the presence of DHA and at 208 nm
in the absence of the fatty acid as a function of protein/DHA ratio was reported (Fig. 6.4).
- 97 -
Fig. 6.3. CD measurements. Far-UV CD spectra of aS, A53T, E46K, A30P in the absence and in the
presence of DHA at different molar ratio. Spectra were recorded in PBS pH 7.4, at a protein
concentration of 5 µM, and in the absence or in the presence of DHA in a final molar ratio
protein:lipid of 1:25, 1:50, 1:60, 1:70 and 1:80 for all proteins.
A30P shows a slight reduced ellipticity and requires more DHA to complete its
conformational transition. Indeed, while aS, E46K and A53T CD signals at 208 and 222 nm
do not increase further at a molar ratio of 1:50, A30P requires more that 350 µM of DHA
(protein/DHA 1:70) to reach the saturation. So accordingly to previous results (Bodner et
al., 2010), it seems that A30P does not have the same affinity for DHA as the other
mutants and aS.
- 98 -
Fig. 6.4. Ellipticity at 208 nm as a function of DHA/protein ratio. Black circles refer to aS, red
circles to A30P, green circles to A53T and yellow circles to E46K.
6.2 Proteolytic mapping of the complex protein/DHA
To define the region(s) of interaction of aS variants with DHA, an approach based
on proteolytic digestion and mass spectrometry was used as previously done for aS (De
Franceschi et al., 2009). This strategy relies on the consideration that regions of the
protein normally available to proteases exhibit limited accessibility when involved in
interaction with lipids (Fontana et al., 2004; Polverino de Laureto et al., 2006). We used
proteinase K (pK) (Ebeling et al., 1974), a particularly voracious protease, which displays
broad substrate specificity to correlate the site of enzyme fission with enhanced
backbone flexibility or local unfolding of the substrates. Moreover this protease retains
proteolytic activity in the presence of DHA (De Franceschi et al., 2009). Proteolysis
experiments were conducted in the absence and in the presence of DHA using a ratio
with the protein of 1:70 to be sure that the equilibrium between the free and bound
molecule were shifted towards the bound one. From previous studies, we know that aS
displays the same pattern of proteolysis in the presence of DHA in ratio 50:1 -70:1 on the
protein.
- 99 -
In the absence of DHA the protein variants are readily fragmented, as already
observed for aS (De Franceschi et al., 2009), according to the fact that these proteins are
unfolded in solution and prone to protease attack. A remarkable fact concerns the
behaviour of A30P. Intact A30P is, indeed, found in the proteolytic mixture after 1 hour of
incubation with the protease, and after 3 hours of incubation is completely cleaved by pK.
At variance all other proteins are completely degraded by the protease just after few
minutes of reaction. The chromatograms RP-HPLC of the proteolytic mixture of A30P and
E46K with pK in the absence of DHA after 1 hour of incubation are reported in Fig. 6.5 to
evidence this aspect.
Fig. 6.5. RP-HPLC chromatograms of the proteolytic mixture of A30P and E46K with pK in the
absence of DHA after 1 and 3-hr of incubation. The fractions are collected and analyzed by mass
spectrometry to identify the peaks.
The proteolysis of the variants with pK in the presence of DHA is stopped after 5
min (Fig. 6.6) and 1 hour of incubation (Fig. 6.7), to see the initial and the late sites of
- 100 -
fragmentation. In all species the initial sites of proteolysis are located in the protein
segment 89-92. Indeed, the intact protein is the main species after 5-min of incubation
and only few peaks of low intensity are visible in the chromatogram. The fractions were
analyzed by mass spectrometry (Table 6.1).
Fig. 6.6. RP-HPLC chromatograms of the proteolytic mixture of aS, A30P, A53T and E46K with pK in
the presence of DHA with a molar ration protein:lipid 1:70, after 5 min of incubation. Proteolysis
were conducted with proteinase K in a E:S ratio of 1:1000. The fractions are collected and
analyzed by mass spectrometry to identify the peaks.
The main species found in the proteolytic mixture correspond to full length
protein, and in very low amounts to fragments 1-89 and 1-92 and the complementary
fragments 90-140 and 93-140, indicating that the proteins are initially cleaved at the
peptide bonds Ala89-Ala90 and Thr92-Gly93. After 1-hr of proteolysis the predominant
- 101 -
product observed for aS is the peptide 1-72 (MM 7299.9 Da) (De Franceschi et al., 2009).
The fragment 1-89 (MM 8839.7 Da) does not accumulate and it is further cleaved forming
fragment 1-72. This species remains in the proteolysis mixture also after prolonged (3-hr)
incubation with the protease (De Franceschi et al., 2009). Fragment 90-140 seems to be
quite resistant to proteolysis and fragments 93-140, 95-140 and 126-140 are produced in
minor extent. In the case of E46K after 1-hr of proteolysis the main species are fragments
1-50 and 1-72 (Fig. 6.7 and Table 6.2), showing a remarkable difference with aS. For A30P
an unexpected resistance to proteolysis is shown, considering that in the presence of DHA
there is still intact protein in the mixture after even after 3-hr of reaction with pK.
Unfortunately we don’t have data regarding the prolonged proteolysis of A53T.
Fig. 6.7. RP-HPLC chromatograms of the proteolytic mixture of A30P and E46K with pK in the
presence of DHA with a molar ration protein:lipid 1:70, after 1 and 3-hr min of incubation. The
fractions are collected and analyzed by mass spectrometry to identify the peaks.
- 102 -
90-140
93-140
95-140
73-140
1-89
1-72aS
90-140
93-140
95-140
1-89
1-72A53T
90-140
93-140
95-140
1-89
1-72A30P
90-140
93-140
95-140
73-140
1-89
1-72E46K
1-50
90-140
93-140
95-140
73-140
1-89
1-72aS
90-140
93-140
95-140
73-140
1-89
1-72aS
90-140
93-140
95-140
1-89
1-72A53T
90-140
93-140
95-140
1-89
1-72A53T
90-140
93-140
95-140
1-89
1-72A30P
90-140
93-140
95-140
1-89
1-72A30P
90-140
93-140
95-140
73-140
1-89
1-72E46K
1-50
90-140
93-140
95-140
73-140
1-89
1-72E46K
1-50
Fig. 6.8. Scheme of proteolysis. The main cleavage sites for aS, E46K, A30P and A53T with PK are
reported.
6.3 Aggregation of as variants in the presence of DHA.
A general consensus is that these aS variants form insoluble fibrillar aggregates
with antiparallel β-sheet structure upon incubation at physiological temperature and are
able to accelerate fibril formation. However their precise effects at early stages of the aS
aggregation process remain unknown. In respect to the tendency to oligomerize, it seems
that E46K produces an oligomer distribution in which the highest observed oligomer
order is bigger than that of aS, while A30P produces an oligomer distribution with a lower
oligomer order than aS (Ono et al., 2011). We have studied the behaviour of the variants
upon incubation in the presence of DHA. Aggregation process was followed by gel
filtration (GF), TEM, circular dichroism (CD) and RP-HPLC. The results were compared to
those obtained for wild type aS.
The mixtures of proteins and DHA (molar ratio P/DHA 1:50) were analyzed by GF
chromatography with the purpose of correlating the physical properties of the samples
with their chemical composition. Aliquots corresponding to different times of incubation
(from 0 to 48 hr) of the mixture composed of protein and DHA were loaded onto a
Superdex 75 column. The GF profile shows a major species eluting at 24 min (Fig. 6.9) and
a minor species (1%) with lower retention time (RT 20 min) for all variants. After 3 h of
incubation, the fraction of the low RT species increases, and after 48 h this species is the
main component of the mixture (Fig. 6.9). Comparing the four different proteins, it is
- 103 -
evident that a difference resides in the yield of oligomers. A53T has a behaviour quite
similar to aS. Conversely the peak of oligomers in E46K is quite low and elutes split in
three forms with different RT. In the case of A30P the yield in oligomers appears higher
than the others.
Fig. 6.9. Gel filtration analysis. GF chromatograms of the mixture of aS, A53T, E46K and A30P
with DHA. Aliquots were taken from the mixtures at 3, 24 and 48-hr of incubation. The
chromatogram relative to mixture just after preparation is also reported.
The fractions relative to oligomers were collected and analyzed by TEM, shown in
Fig. 6.10. TEM analysis showed that the chromatographic fraction corresponding to
oligomers of A30P and A53T contains heterogeneous population of aggregates in which a
part has a spherical morphology, with diameters ranging from 15 to 35 nm. For E46K we
were not able to obtain better images, so we don’t have definitive results. In the figure,
- 104 -
the TEM images of fibrils produced by the variants under the same experimental
conditions in the absence of DHA are shown on the right. All mutants are able to form
long and unbranched fibrils in the absence of the fatty acid.
Fig. 6.10. TEM pictures. The aggregation of aS variants in the presence of DHA were analyzed by
TEM. Pictures are relative to the oligomeric fractions of A30P, E46K and A53T eluted from GF.
- 105 -
The aggregation process was also followed by CD (Fig. 6.11) and no
conformational change was observed, only a partial reduction of the intensity of the CD
signals as observed for aS, although the spectrum shape does not change over time.
200 210 220 230 240
-30
-20
-10
0E46K
Wavelength (nm)200 210 220 230 240 250
aS
-30
-20
-10
0
[θ] x
10-3
(de
g.cm
2 .dm
ol-1
)
A53T
A30P
Fig. 6.11. CD measurements. Far-UV CD spectra of aS, A53T, E46K, A30P in the presence of DHA
during aggregation. Spectra were recorded in PBS pH 7.4, at a protein concentration of 5 µM. The
spectra relative to 0 (solid lines) and 48 (dashed lines) hr of incubation are reported.
The mixtures of proteins and DHA were injected in RP-HPLC. The chromatogram
corresponding to the starting condition (Fig. 6.12 and Table 6.3) shows two main peaks.
The first peak is around 18 min and corresponds to the monomeric species, and the other
peak is centred at 32 min and includes three peaks (RT of 30.5, 32, and 33 min). As
incubation proceeds, the peak with a RT of 30.5 min corresponding to the oligomeric
species increases. Of note again the RP-HPLC patterns of the three variants are similar to
that obtained from aS (Fig. 6.12), but the intensity of the peak relative to the oligomers
formed by A30P and E46K is lower than the other species. In the case of A30P a
reasonable explanation is based on the possibility that the oligomers were less stable to
- 106 -
the conditions used for RP-HPLC analysis. Further analysis will be done in order to deepen
these aspects.
E46K
15 20 25 30 35
Rel
ativ
e A
bsor
banc
e at
226
nm
aS
A30P
Retention Time (min)15 20 25 30 35
A53T
Fig. 6.12. RP-HPLC analysis. Chromatograms of aS, A53T, E46K and A30P during aggregation in
the presence of DHA, after 0 (dashed lines) and 48- (solid lines) hours.
- 107 -
Table 6.1. Chemical characterization of peptide material corresponding to mayor peaks of
the chromatograms relative to the fragmentation of aS and its mutants in the presence of
DHA with pK after 5 min of incubation.
Molecular Mass (Da) RTa
(min) Foundb Theoretical
c
Speciesd
18.4
5633.10±0.11
5390.01±0.11
5633.0
5389.7
90-140
93-140
29.7 7174.57±0.06 7173.7 73-140
30.1 8846.32±0.74 8845.2 1-89
30.4 9088.98±0.59 9088.5 1-92
30.8 14477.41±0.4 14476 1-140+1ox
31.5 14460.05±0.27 14460 1-140
18.4
5633.59±0.20
5390.16±0.11
5633.0
5389.7
90-140
93-140
29.6 8871.96±0.02
8942.10±0.13
8871.2
8942.3
1-89
1-90
29.9 9115.96±0.26
8816.91±0.57
9114.5
8815.6
1-92
57-140
30.4 14486.34±0.20 14486.2 1-140
18.7
5632.83±0.10
5389.76±0.05
5633.0
5389.7
90-140
93-140
30.0 9115.56±0.16 9118.5 1-92
30.4 8876.64±0.09 8875.2 1-89
30.8 14490.76±0.77 14490.2 1-140
31.6 14509.58±0.35 14506.2 1-140+1ox
32.3 14490.76±0.77 14490.2 1-140
18.5 5185.58±0.02 5185.1 95-140
19.0 5632.83±0.10
5389.76±0.05
5633.0
5389.7
90-140
93-140
27.8 7171.30±0.90 7172.7 73-140
29.8 8845.12±0.26
9088.55±0.28
8844.2
9087.5
1-89
1-92
30.2 14490.98±0.68 14491.2 1-140+2ox
30.5 14475.95±0.33 14475.2 1-140+ox
30.8 14459.75±1.27 14459.2 1-140
a Peptides or proteins were purified by RP-HPLC and listed in order of
retention times (RT). b
Experimental molecular masses determined by ESI-MS. c Molecular masses calculated from the amino acid sequence of aS.
d Species containing Met residues are present also as oxidized form.
aS
A30P
A53T
E46K
- 108 -
Table 6.2. Mass-spectrometry identification of peptide material corresponding to major
peaks of the chromatograms in Fig. 30 relative to the fragmentation of A30P and E46K in
the presence of DHA with pK after 1- and 3-hr of reaction.
Molecular Mass (Da) RTa
(min) Foundb Theoretical
c
Speciesd
27.8 7347.29±0.28
7030.93±0.14
7346.49
7031.12
1-72 ox
1-69
27.9 7331.25±0.10 7330.49 1-72
29.4 8872.86±0.15 8871.23 1-89
30 14520.51±0.36
14537.35±0.98
14518.22
14534.22
1-140
2ox
1-140 30.3
14488.86±0.28
14504.60±0.29
14486.22
14502.22
1-140
1-140 ox
28.4
5162.84±0.02
7319.19±0.09
5661.68±0.57
5318.98±0.10
5163.1
7319.52
5661.68
5319.28
1-50
1-72 ox
1-56
1-52
29.2
7303.89±0.63
8845.47±1.9
9087.92±0.04
7303.52
8844.26
9087.52
1-72
1-89
1-92
30.1 14460.360.04 14459.24 1-140
a, b, c, d
see reference Table 6.1.
A30P
E46K
- 109 -
Table 6.3. Chemical characterization of protein material corresponding to mayor peaks of
the chromatogram relative to the aggregation of aS and its mutants in the presence of
DHA.
Molecular Mass (Da) RTa
(min) Foundb Theoretical
c
Speciesd
14508.13 (±0.05) 14508.1 aS 3ox
14491.8 (±0.5) 14492.1 aS 2ox
19.5 14476.1 (±0.3) 14476.1 aS 1ox
21 14459.92 (±0.01) 14460.1 aS
14801.9 (±0.05) 14802.1 aS 1ox 326
14817.1 (±0.7) 14818.1 aS 2ox 326 31
14831.3 (±0.9) 14834.1 aS 3ox 326
14522.4(±1.1) 14522.2 A53T 2ox
17.8 14554.6 (±0.2) 14554.2 A53T 4ox
18.5 14506.3 (±0.6) 14506.2 A53T 1ox
18.9 14490.5 (±0.3) 14490.2 A53T
31.5 14864.6 (±1.7) 14864.2 A53T 3ox 326
14464.8 (±0.6) 14459.2 E46K
14479.1 (±0.6) 14475.2 E46K 1ox
17
14496.6 (±0.6) 14491.2 E46K 2ox
31 14791.6 (±1) 14785.2 E46K 326
14486.9 (±0.2) 14486.2 A30P
14502.6 (±0.6) 14502.2 A30P 1ox
14518.6 (±0.3) 14518.2 A30P 2ox
17.4 14534.0 (±1.2) 14534.2 A30P 3ox
17.8 14486.9 (±0.2) 14486.2 A30P
31.5 14859.8 (±3.2) 14860.2 A30P 3ox 326 e32 326.28 (±0.08) 326.24 DHA (-2H)
33 328.29 (±0.16) 328.24 DHA
a, b, c, d
see reference Table 6.1. e
Peaks eluted at 32 and 33 min correspond to DHA for all analyzed protein.
aS
A53T
E46K
A30P
- 110 -
- 113 -
7. DISCUSSION AND CONCLUSION
There is growing interest in finding a possible link between aS toxicity in
synucleinopathies and aS-lipid interaction. The precise biological function of aS is still
under investigation, but it is implicated in a range of interactions with phospholipid
membranes and free fatty acids. A current hypothesis about its pathological behaviour is
that the association of aS with oxidized lipid metabolites can lead to mitochondrial
dysfunction in turn leading to dopaminergic neuron death and thus to Parkinson's disease
(Ruipérez et al., 2010). aS toxicity might also be related to abnormal membrane
interactions and alterations in vesicles trafficking (Auluck et al., 2010). Many studies link
toxicity to the existence of various intermediate structures, such as oligomers originating
in early stages of aS fibrillation, and their specific interaction with membranes. Such
intermediates are yet not fully characterized and there are several different possible
mechanisms of toxicity (Fig. 7.1).
Fig. 7.1. Schematic representation of interconnectivity between amyloid formation and membrane
disruption. Top: The process of amyloid-fibril formation. Amyloid formation involves the
misfolding of soluble proteins into β-sheet oligomers, which further aggregate into protofibrils,
including ringlike annular protofibrils, and then into amyloid fibrils. Bottom: The role of
membranes in amyloid formation and toxicity. Soluble proteins bind to membrane surfaces with a
shift to α-helix structure. The accumulation of proteins on the surface of the membrane induces
their aggregation. When a critical threshold concentration is reached, a trans-membrane pore
(annular protofibril) develops in the membrane and enables the leakage of membrane contents.
As other possible or coexistent mechanisms, annular protofibrils formed in solution may insert
into the membrane, undefined prefibrillar aggregates may bind to the membrane surface and
induce membrane thinning, and lipids may be extracted from the membrane and incorporated
into the developing fibril in a detergent-like process (from Lashuel and Butterfield, 2010).
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Many evidences are in favour of oligomers able to form membrane pores (Kostka et al.,
2008; Zakharov et al., 2007). A new model of amyloid interaction with membranes by a
"raft-like" mode of insertion could explain important destabilization of membranes and
thus amyloid toxicity (Berthelot et al., 2013). Many reports suggest that PUFAs are strictly
connected to neurological disorders, including Parkinson’s disease (Marszalek & Lodish,
2005). Specifically, alterations in PUFAs levels have been found related to aggregation of
aS (Necula et al., 2003; Perrin et al. 2001; Sharon et al., 2003; Assayag et al., 2007). It has
been proposed that aS could interact with free FAs (Sharon et al., 2001; Broersen et al.,
2006), or, alternatively, with FAs in a micellar or bilayer state (Necula et al. 2003; Lücke et
al., 2006). Interestingly, It has been shown that elevated brain DHA levels accelerate aS
accumulation and oligomerization: treating dopaminergic cells expressing aS with
polyunsaturated fatty acids (PUFAs) induced the formation of stable oligomers whereas
saturated fatty acids did not. These oligomers were associated with cyto-toxicity, whereas
the development of Lewy-like inclusions appeared to be protective (Assayag et al., 2007).
A recent study demonstrated that dietary changes in brain DHA levels affect aS
cytopathology in mice transgenic for the PD-causing A53T mutation in human aS. A diet
enriched in DHA increased the accumulation of soluble and insoluble neuronal aS, neuritic
injury and astrocytosis (Yakunin et al., 2012).
We previuosly produced in vitro oligomeric species of aS in the presence of DHA,
which resulted toxic in cultured dopaminergic cells (De Franceschi et al., 2009; 2011). The
aim of this thesis is to characterize the main biophysical properties of this type of
oligomers, in order to explain their possible mechanism of toxicity. Moreover, studies
about their chemical modification have been conducted, considering also differences that
may occur between aS and its variants A30P, E46K, H50Q and A53T.
7.1 aS/DHA oligomers characterization
In the presence of DHA, it is induced the formation of relatively stable oligomers that
are off-pathway in aS aggregation process (De Franceschi et al., 2011). The first aim of
this study was to better characterize oligomers structure and shape, in order to correlate
them with their activity. We have used a number of biophysical techniques such as TEM,
AFM and DLS. These measurements show that aS/DHA oligomers are a heterogeneous
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population of species, with diameters ranging from 12-30 nm. Different types of
oligomers have been described in literature, depending on the conditions of preparation.
Indeed, different conditions such as the presence of metals or lipids can affect the shape
and the dimension of oligomers (Paik et al., 2002; Lee et al., 2002). Moreover, studies of
the kinetics of fibril formation have given important insights into the overall mechanism
of amyloid assembly, but little is known in any detail about the oligomeric structure
(Lashuel et al., 2002; Luheshi et al., 2007; Winner et al., 2011). A variety of distinct
morphologies of aS oligomers have been observed using imaging techniques, such as
atomic force microscopy or transmission electron microscopy (Conway et al., 2000; Ding
et al., 2002; Lashuel et al., 2002; Hoyer et al., 2004). Structural studies on aS oligomers
have also been carried out using FTIR, Raman, CD, and fluorescence spectroscopy (Apetri
et al., 2006; Goldberg and Lansbury, 2000; Hong et al., 2008; Nath et al., 2010;
Thirunavukkuarasu et al., 2008), which have revealed the formation of various oligomeric
structures during aS aggregation, consistent with a progressive increase in β sheet
structure occurring concomitantly with the formation of more ordered aggregates.
Oligomers formed in the presence of DHA show a similar size and morphological features
with those previously described, but they acquire α-helical conformation (De Franceschi
et al., 2009; 2011). This structure is almost partially lost after a gel filtration purification
step. We presume that exchangeable DHA, not the covalently bound one, is removed
and with it the effect on oligomers structure. Consequently the oligomers acquire a
partly folded state, significantly different from the natively unfolded structure of
monomeric aS. These partly folded oligomers are able to acquire again α-helical
structure upon addition of DHA. This behaviour lead us to speculate about a possible
structure model of these oligomers, sectioning the structure of oligomers into two parts,
the N-terminal and the NAC region, and evaluating separately their contribute. In
monomeric aS, the N-terminal region is essential for membrane recognition and for
cooperative formation of helical domains. By CD and isothermal titration calorimetry,
Bartels and colleagues (2010) tested different fragments and domains of aS for their
binding affinity, concluding that N-terminus results necessary for the membrane-induced
helical folding and the interaction of the first 25 residues with lipids is driven by
electrostatic attraction. Transferring this to oligomers, since they in their partly folded
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state can undergo conformational transition in the presence of lipids and membranes, it
is reasonable to assume that the N-terminal region, or part of it, is free.
Another property of aS/DHA oligomers is that they are off-pathway and do not
proceeds in the aggregation process, even in the presence of membranes. In aS,
experiments on fragments of NAC have enabled this region as responsible for
aggregation, in particular fragment 8-18 of NAC is the smallest fragment that aggregates
and forms fibrils (El-Agnaf et al., 2002). Furthermore, membranes work as a catalyst of
aggregation (Berthelot et al., 2013) since membrane-bound aS can generate nuclei that
seed the aggregation also in vivo (Lee et al., 2002). So it seems that the NAC region
(residues 61-95) in aS/DHA oligomers is not available or is hidden in their interior. In
conclusion aS/DHA oligomers have two main structural features: the conformational
sensitivity to environment for the ability to interact with lipids and to undergo structural
transition, and secondly the stability under conditions that favours aggregation. The
overall structure of the oligomers could be stabilized by hydrophobic interactions
deriving from the association of NAC regions.
7.2 aS/DHA oligomers activity on membranes
Here we have studied aS/DHA oligomers activity on membranes in an attempt to
understand their mechanism of toxicity, because the latter, as yet said, is object of
debate in the literature for the difficulty to define a unifying picture of the toxic activity.
The controversy springs from both the transient nature of aS oligomers and from the
many different types of oligomers that have been described. Volles and colleagues
(2001), demonstrated that protofibrillar aS, in contrast to the monomeric and the fibrillar
forms, binds synthetic vesicles very tightly via a β-sheet-rich structure and transiently
permeabilizes these vesicles. An interesting property of aS/DHA oligomers is their ability
to permeabilize membranes, as verified using a leakage assay from unilamellar
phospholipid vesicles. By calcein leakage test we demonstrated that aS/DHA oligomers
destabilize both LUV and SUV composed of negative charged phospholipids.
Interestingly, vesicles composed of only 50% negative-charged phospholipids show really
low extent of calcein release after incubation with aS oligomers, even if this kind of
vesicles is able to induce acquisition of α-helix structure on aS/DHA oligomers, even if
with a minor extent than that induced by 100% acidic phospholipids. This result is in line
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with a previously reported behaviour of aS oligomers (Van Rooijen et al., 2008), that bind
negative charged membranes acquiring α-helix structure. In a similar way, these
oligomers are not able to induce calcein leakage in vesicles of 50% zwitterionic lipids,
allowing to conclude that membrane binding of aS does not necessarily lead to vesicle
permeabilization.
We tested also the activity of aS/DHA oligomers on dopaminergic cells. Treatment
with oligomers significantly increases the number of cells internalizing the membrane-
impermeant dye propidium iodide. These results suggest that membranes can be a
possible target of aS oligomers activity. This can be particularly harmful for neuronal
cells, where electrical activity and action potential firing are finely regulated by transient,
voltage-gated channel-mediated variation of membrane potential and intracellular
calcium concentration. Indeed, increased membrane permeability could result in a
variety of intracellular processes and leads to cytotoxicity, as well as dissipation of
sodium and potassium gradients with deleterious impact on electrical neuronal activity.
Several mechanisms have been proposed to explain oligomers activity on
membranes. One possible mechanism is that of the pore-like mechanism (Zakharov et
al., 2007; Kostka et al., 2008; Lashuel and Butterfield 2010). Protofibrils with β-sheet-rich
structure transiently permeabilizes vesicles and the activity is comparable for aS WT and
its A53T and A30P mutants (Volles et al., 2001). A thinning effect due to lipid extraction
from the bilayer has been also reported. aS WT, A53T and the designed A57T mutant
were found to follow the same mechanism of polymerization and membrane damage,
involving the extraction of lipids from the bilayer and their clustering around growing α-
synuclein aggregates (Reynolds et al., 2011). Leakage could be due also to a complete
disruption of the membrane, reported for mellitin (Bechinger and Lohner, 2006), or a
transient membrane destabilization, possibly related to the intrinsic instability of the
bilayer. Indeed, vesicles composed of negatively charged lipids, which are generally used
for measuring aS-lipid interactions, are unstable to protein adsorption in general (van
Rooijen et al., 2010). The pore-like hypothesis is especially accepted for those proteins
forming oligomers or protofibrils with annular or ring-like structure (Butterfield and
Lashuel 2010). In our case the leakage activity tested on synthetic liposomes shows
selectivity of markers size, evidencing that the average dimension of the aperture should
be between 1 and 4 nm (Mazzuca et al., 2010). The enhanced membrane-
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permeabilization activity of amyloid oligomers relative to that of soluble monomers and
mature fibrils and the reported size dependence with respect to dye leakage from model
vesicle membranes are considered consistent with the pore-like mechanism (Butterfield
and Lashuel 2010). Other characteristic are required to assume the formation of pores,
such as the induction of single-ion-channel currents characteristic of ion-channel or pore-
forming proteins. The activity of aS/DHA oligomers on a planar lipid membrane system
seems due to a non-specific membrane permeabilization rather than to the formation of
structured membrane apertures like those previously demonstrated also for monomeric
aS (Tosatto et al., 2012).
The complete disruption effect could be excluded by DLS and microscopy
measurements of aS/DHA oligomers in the presence of phospholipids vesicles. Indeed
DLS measurements of both LUV and SUV in the presence of aS/DHA oligomers show that
the vesicles size distribution is modified, but TEM shows no changes to the overall
vesicles morphology. The reported effect of Triton X-100 on vesicles measured by DLS
clearly exclude a similar effect by oligomers. In conclusion, aS/DHA oligomers interacting
with negatively charged membranes induce a perturbation of the phospholipid bilayer
with the release of encapsulated small molecules. Oligomeric molecules remain
entrapped on the vesicles, as peripheral membrane proteins, acquiring α-helical
structure. Damaging of membrane structural integrity seems to be an essential step in
the cytotoxic activity of aS oligomers formed in the presence of DHA.
This part of the thesis is object of a publication (Fecchio C., De Franceschi G., Relini
A., Greggio E., Dalla Serra M., Bubacco L., Polverino de Laureto P (2013) α-Synuclein
Oligomers Induced by Docosahexaenoic Acid Affect Membrane Integrity. PlosOne
8:e82732.
7.3. Chemical modification of aS in the presence of DHA
The chemical protein modifications, that form under oxidative stress conditions,
occur on specific amino acid residues. The direct oxidation of proteins by ROS involves
Lys, Arg, Pro and Thr residues. The secondary reactions with reactive derivatives
(ketoamines, ketoaldehydes, deoxyosones) produced by sugars oxidation product occur
especially on Lys, while the formation of adducts of oxidized lipids derived from the
metal-catalysed oxidation of PUFA involves Lys, Cys and His residues (Esterbauer et al.,
- 119 -
Fig. 2. Schematic representation of Michael
addition of 4-HNE on His50, contained in the
fragment E46-K58.
1991; Uchida and Stadtman, 1992; Refsgaard et al., 2000; Dalle Donne et al., 2006). In
the case of aS, the modifications on Lys residues can affect the charge distribution of the
basic KXKE repeats of the N-terminal region, and so influence the interaction with
membranes that is primarily mediated by a charge effect (Davidson et al., 1998; van
Rooijen et al., 2010). One of the main features of aS/DHA oligomers is the chemical
heterogeneity that derive from the presence of covalently bound DHA and of oxidative
additional modifications (De Franceschi et al., 2011). In previous studies we detect the
presence of modification, but we didn’t identify which amino acids are involved, so
another aim of the present work was to define the modified residues in aS/DHA
oligomers and eventually the role of these modifications in their activity.
A first attempt was done to detect the increase of carbonylation (Dalle Donne et
al., 2006) of aS in the presence of DHA. A reaction with by DNPH was used that have
demonstrated an increased presence of carbonyls, but unfortunately it was not possible
to assess which residues were mainly modified. Only a fragment containing the Δ mass of
180 Da was found and it corresponds to the sequence 24-32. This peptide contains Lys32
as possible target of carbonylation. However the presence of a single modification does
not justify the signals obtained in UV and RP-HPLC analyses. It is reasonable that residues
in the protein are randomly modified and so it is difficult to detect them.
DHA-adduct is the most evident modification, among the several possible ones,
so we focused on its characterization.
Trypsin digestion of the aS/DHA
oligomers followed by peptide 'finger-
printing' revealed that DHA binds the
peptide 46EGVVHGVATVAEK58, providing
an indirect evidence that His50 is
modified. This could be predictable
since the reactivity of lipid peroxidation
products, such as allylic radicals, is
known and involves Cysteine, Histidine
and Lysine residues (Uchida et al.,
1997). Moreover, 4-hydroxy-2(E)-
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nonenal, a product of peroxidation of lipids, preferentially binds to His50 on aS (Fig. 2,
from Trostchansky et al., 2006), or more rarely to Lys60 and Lys69 (Bae et al., 2013;
Xiang et al., 2013,). His50 results a suitable target for the formation of an adduct with
DHA. In view of the fact that His50 is preferentially modified by DHA, in comparison with
the several lysine residues present in the polypeptide chain, we investigated the
importance of this residue by using a mutant containing a Gln in spite of His in position
50. Interestingly this specific variant has been recently found in a familiar form of PD.
H50Q behaviour in the presence of DHA is very similar to that of aS. H50Q acquires α-
helix structure and by limited proteolysis a similar interaction with DHA was evidenced.
Moreover, also the aggregation process results similar to that of aS and oligomers form.
Surprisingly, a mass increase of 326 Da is still detectable on the protein, and sometimes
more than one FA adduct was found, meaning that other residues were modified. This
result suggests that the position of the modification on aS is not essential for the
formation of oligomers. The preference for His50 could be due to chemical reasons, since
the reaction toward His is favoured. Indeed, His50 is surely in excess on reactive DHA,
that is its radical form, which constitutes about 0.3% of the initial content of FA.
After His, the binding of DHA can occur at the level of Lysine residues, that are 14
in the whole protein. It was not possible to detect any modified lysine by finger printing
analysis of H50Q oligomers. We can explain it considering that it was possible to find
modified His50 because it was the preferred site of modification. On the contrary,
without His all the 14 lysines are possible target of DHA binding, leading to the formation
of a heterogeneous population of H50Q, modified in different lysine residues. As a
consequence, the extent of modification on a specific lysine is too low to be detectable
with this kind of analysis.
Finally the fact that the oligomers obtained from aS and H50Q have the same
extent of activity on synthetic membrane, allowing to conclude that the position of the
modification is not essential even for oligomers activity.
7.4 aS variants in the presence of DHA
To complete the study, also the other three known mutants found in
familiar forms of PD (A30P, A53T and E46K) were investigated. In the presence of DHA, all
mutants acquire α-helix structure in a similar way, but A30P in minor extent. Upon
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incubation at a molar ratio protein/lipid 1:50, all the proteins form stable oligomers but,
interestingly, the oligomers formation rate was different, resulting in a minor oligomeric
content for E46K and A30P. To define the region of aS more directly interacting with DHA,
proteolysis experiments coupled with mass spectrometry have been performed. aS, as a
natively unfolded protein, is largely sensitive to proteases because it lacks secondary and
tertiary structure (Uversky, 2002). As a matter of fact, there are no regions with such
persistent structure as to hinder protease’s attack. Upon binding to DHA, aS appears to be
quite resistant to proteolysis, as expected from the fact that the polypeptide has adopted
an α-helix conformation which strictly involves the first 70 amino acid residues. A
considerable accessibility of aS polypeptide chain to proteinase K is confined only at the
level of region 70-90, providing evidence that this segment is the most flexible and
sufficiently protruded to be protease-sensitive (Hubbard et al., 1994; Fontana et al.,2004).
Comparing proteolytic patterns of aS and its variants in the presence of DHA, it became
evident that first cleavage sites are identical for all the proteins, suggesting that the
overall interaction with membrane is mediated by the same region encompassing the first
~100 amino acids (De Franceschi et al., 2009). Prolonging the proteolysis to 1 and 3 hr for
A30P and E46K, it is shown that fragments that accumulate in the proteolytic mixture are
1-72 for A30P, and 1-50 for E46K. To explain these differences, we can consider the data
reported by Bodner et al. (2010). The mutation of E in K raises the net charge of the first
100 residues from +4 to +6, resulting in higher affinity for negative charged lipid. By NMR
it was observed that this fact determines a slower dissociation from lipid. As a
consequence E46K increase the bound fraction in a SL1 binding mode, in which the first
10 or 24 N-terminal residues adopt a stable α-helical conformation upon lipid binding,
while the lasting ~25-140 residues are dynamically disordered (Fig. 25). A second binding
state, SL2, populated by aS, engages the whole N-terminal domain until to the residue
~100. E46K in SL1 state allows the protease to cleave peptide bond H50-G51 located in
the dynamically disordered region 25-100.
A30P doesn’t form a canonical α-helix upon binding to lipids, for the presence of
proline residue. This determines a reduced association rate to lipids and a shift of the
equilibrium between SL1 and SL2 binding mode towards the SL1 one. Intriguingly the
A30P is not fragmented at the level of peptide bond H50-G51, since intact A30P is found
also upon prolonged incubation with the protease. This doesn’t imply necessary presence
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of regular secondary structure but can be due to a backbone rigidity imposed by proline
(Polverino de Laureto et al., 2006). In conclusion, in the presence of DHA, the variant
E46K appears to be highly susceptible to proteases hydrolysis in correspondence of the
region 50-89, included in the NAC region, while aS in the region 73-89. A30P shows an
unusual rigidity. However the initial sites of proteolysis clearly indicate that in the
presence of saturating concentration of DHA, considerable accessibility of the
polypeptide chains to proteinase K is located to residues 70-90, providing evidence that
this segment for all variants, by limited proteolysis criteria, is the most flexible and
protruded to be protease-sensitive.
- 123 -
8. REFERENCES
- Aebersold R., Goodlett DR. (2001) Mass spectrometry in proteomics. Chem. Rev.
101:269–295.
- Alim M.A., Hossain M.S., Arima K., Takeda K., Izumiyama Y., Nakamura M., Kaji H.,
Shinoda T., Hisanaga S., Ueda K. (2002) Tubulin seeds alpha–synuclein fibril formation. J
Biol Chem. 277:2112–7.
- Andersen JK. (2009) Arvid Carlsson: an early pioneer in translational medicine. Sci
Transl Med. 14:2–3.
- Apetri M.M., Maiti N.C., Zagorski M.G., Carey P.R., Anderson V.E. (2006) Secondary
structure of alpha–synuclein oligomers: characterization by raman and atomic force
microscopy. J Mol Biol. 355:63–71.
- Appel–Cresswell S., Vilarino–Guell C., Encarnacion M., Sherman H., Yu I., Shah B., Weir
D., Thompson C., Szu–Tu C., Trinh J., Aasly JO., Rajput A., Rajput AH., Jon Stoessl A.,
Farrer M.J. (2013) Alpha–synuclein p.H50Q, a novel pathogenic mutation for
Parkinson's disease. Mov Disord. 28:811–3.
- Assayag, E. Yakunin, V. Loeb, D.J. Selkoe, R. Sharon (2007) Polyunsaturated fatty acids
induce alpha–synuclein–related pathogenic changes in neuronal cells. Am J Pathol.
171:2000–2011.
- Barcelo–Coblijn G., Golovko M.Y., Weinhofer I., Berger J., Murphy E.J. (2007) Brain
neutral lipids mass is increased in alpha–synuclein gene–ablated mice. J Neurochem.
101:132–141.
- Bartels T., Choi J.G., Selkoe D.J. (2011) α-Synuclein occurs physiologically as a helically
folded tetramer that resists aggregation. Nature 477:107–110.
- Bendor JT., Logan TR., Edwards RH. (2013) The function of α–synuclein. Neuron
79:1044–1066.
- Bertoncini C. W., Jung Y. S., Fernandez C. O., Hoyer W., Griesinger C., Jovin T. M. &
Zweckstetter M. (2005) Release of long–range tertiary interactions potentiates
aggregation of natively unstructured alpha–synuclein. Proc Nat Acad Sci USA
102:1430–1435.
- Beyer K., (2006) alpha–Synuclein structure, posttranslational modification and
alternative splicing as aggregation enhancers, Acta Neuropathol. 112:237–251.
- Beyer K. (2007) Mechanistic aspects of Parkinson's disease: alpha–synuclein and the
biomembrane. Cell Biochem Biophys. 47:285–99.
- Bieschke J., Q. Zhang, D.A. Bosco, R.A. Lerner, E.T. Powers, P. Wentworth Jr., J.W. Kelly,
(2006) Small molecule oxidation products trigger disease–associated protein
misfolding. Acc. Chem. Res. 39:611–619.
- Bisaglia M., Tosatto L., Munari F., Tessari I., de Laureto P.P., Mammi S., Bubacco L.,
(2010) Dopamine quinones interact with alpha–synuclein to form unstructured
adducts. Biochem. Biophys. Res. Commun. 394:424–428.
- Biskup S., West A.B. (2009) Zeroing in on LRRK2–linked pathogenic mechanisms in
Parkinson's disease. Biochim Biophys Acta 1792:625–33.
- Bodner C.R., Maltsev A.S., Dobson C.M., Bax A. (2010) Differential phospholipid binding
of alpha-synuclein variants implicated in Parkinson's disease revealed by solution NMR
spectroscopy. Biochemistry 49:862-71.
- 124 -
- Braak H., Del Tredici K., Rüb U., de Vos R. A., Jansen Steur E. N., Braak E. (2003) Staging
of brain pathology related to sporadic Parkinson's disease. Neurobiol Aging
24:197−211.
- Breydo L., Jessica W. Wu, Vladimir N. Uversky (2012) α–Synuclein misfolding and
Parkinson's disease. Biochimica et Biophysica Acta (BBA) – Molecular Basis of Disease
1822:261–285.
- Broersen K., van den Brink D., Fraser G., Goedert M., Davletov B. (2006) Alpha–
synuclein adopts an alpha–helical conformation in the presence of polyunsaturated
fatty acids to hinder micelle formation. Biochemistry 45:15610–16.
- Burrè J, Sharma M, Tsetsenis T, Buchman V, Etherton MR, Südhof TC (2010) α–
Synuclein promotes SNARE–complex assembly in vivo and in vitro. Science 329:1663–
1667.
- Bussell R. Jr & Eliezer D. (2001) Residual structure and dynamics in Parkinson’s disease–
associated mutants of alpha–synuclein. J Biol Chem. 276:45996–46003.
- Bussell R. Jr, Ramlall T.F., Eliezer D. (2005) Helix periodicity, topology, and dynamics of
membrane–associated alpha–synuclein. Protein Sci 14:862–872.
- Camandola S., Poli G., Mattson M. P. (2000) The lipid peroxidation product 4–hydroxy–
2,3–nonenal increases AP–1–binding activity through caspase activation in neurons. J.
Neurochem. 74:159–168.
- Castagnet P.I., Golovko M.Y., Barcelo–Coblijn G.C., Nussbaum R.L., Murphy E.J. (2005)
Fatty acid incorporation is decreased in astrocytes cultured from alpha–synuclein
gene–ablated mice. J Neurochem 94:839–849.
- Chaari A., Horchani H., Frikha F., Verger R., Gargouri Y., Ladjimi M. (2013) Surface
behavior of α-Synuclein and its interaction with phospholipids using the Langmuir
monolayer technique: a comparison between monomeric and fibrillar α-Synuclein. Int J
Biol Macromol. 58:190-8.
- Chartier–Harlin M. C., Kachergus B.S., Roumier C., Mouroux V., Lincoln S., Levecque C.,
Larvor L., Andrieux J., Hulihan M., Waucquier N., Defebvre L., Amouyel P., Farrer M.,
Destee A. (2004). α–Synuclein locus duplication as a cause of familiar Parkinson’s
disease. The Lancet 364:1167–1169.
- Chavarría C., José M. (2013) Souza Oxidation and nitration of α-synuclein and their
implications in neurodegenerative diseases. Archives of Biochemistry and Biophysics
533:25–32.
- Chen X., Liu Y.T., Li J.R., Chen L., Xu Y.M., Pan Y.H., Meng X.H., Xing S.H., (2003) Study
on exons 3 and 4 of alpha–synuclein gene in Chinese familial Parkinson disease
patients. Zhonghua Yi Xue Yi Chuan Xue Za Zhi. 20:536–8.
- Childknecht S., Gerding HR, Karreman C, Drescher M, Lashuel HA, Outeiro TF, Di Monte
DA, Leist M (2013) Oxidative and nitrative alpha–synuclein modifications and
proteostatic stress: implications for disease mechanisms and interventions in
synucleinopathies. J. Neurochem. 125:491–511.
- Chiti F., Stefani M., Taddei N., Ramponi G., Dobson C.M. (2003) Rationalization of the
effects of mutations on peptides and protein aggregation rates. Nature 424:805–808.
- Choi W., Zibaee S., Jakes R., Serpell L.C., Davletov B., Crowther R. A. & Goedert M.
(2004) Mutation E46K increase phosholipid binding and assembly into filaments of
human alpha–synuclein. FEBS Lett 576:363–368.
- 125 -
- Cole N.B., Murphy D.D., Grider T., Rueter S., Brasaemle D., Nussbaum R.L. (2002) Lipid
droplet binding and oligomerization properties of the Parkinson’s disease protein
alpha–synuclein. J Biol Chem. 277:6344–6352.
- Conway K.A., Harper J.D. & Lansbury P.T. Jr (1998) Accelerated in vitro fibril formation
by a mutant alpha–synuclein linked to early onset Parkinson’s disease. Nature Med
4:1318–1320.
- Conway K.A., Lee S.J. Rochet J.C., Ding T.T., Williamson R. E. & Lansburt P.T. Jr (2000)
Acceleration of oligomerization, not fibrillation, is a shared property of both alpha–
synuclein mutations linked to early–onset Parkinson’s disease: implications for
pathogenesis and therapy. Proc Nat Acad Sci USA 97:571–576.
- Conway K.A., Rochet J.C., Bieganski R.M. & Lansbury P.T. Jr. (2001) Kinetic stabilization
of the alpha–synuclein protofibril by a dopamine–alpha–synuclein adduct. Science
294:1346–1349.
- Cookson M. R. (2005) The biochemistry of Parkinson’s disease. Annu Rev Biochem
74:29– 52.
- Covy J.P., Giasson B.I. (2011) α–Synuclein, leucine–rich repeat kinase–2, and
manganese in the pathogenesis of parkinson disease. NeuroToxicology 32:622–629.
- Crowther R. A., Jakes R., Spillantini M. G. & Goedert M. (1998) Synthetic filaments
assembled from C–terminally truncated alpha–synuclein. FEBS Lett 436:309–312.
- Dachsel J.C., Wider C., Vilariño–Güell C., Aasly J.O., Rajput A., Rajput A.H., Lynch T.,
Craig D., Krygowska–Wajs A., Jasinska–Myga B., Opala G., Barcikowska M., Czyzewski .,
Wu R.M., Heckman M.G., Uitti R.J., Wszolek Z.K., Farrer M.J., Ross O.A. (2011) Death–
associated protein kinase 1 variation and Parkinson's disease. Eur J Neurol. 18:1090–3.
- Danielson S.R., Held J.M., Schilling B., Gibson B.W., Andersen J.K., (2009) Preferentially
increased nitration of alpha–synuclein at tyrosine–39 in a cellular oxidative model of
Parkinson's disease. Anal. Chem. 81 :7823–7828.
- Dauer, W., Przedborski, S. (2003) Parkinson's disease: mechanisms and models.
Neuron. 39:889−909.
- Davidson W. S., Jonas A., Clayton D. F., George J. M. (1998) Stabilization of alpha–
synuclein secondary structure upon binding to synthetic membranes. J Biol Chem.
273:9443– 9449.
- De Franceschi G., Frare E., Bubacco L., Mammi S., Fontana A., de Laureto P.P. (2009)
Molecular insights into the interaction between alpha–synuclein and docosahexaenoic
acid. J Mol Bio. 394:94–107.
- De Franceschi G., Frare E., Pivato M., Relini A., Penco A., Greggio E., Bubacco L.,
Fontana A., de Laureto P.P. (2011) Structural and morphological characterization of
aggregated species of α–synuclein induced by docosahexaenoic acid. J Biol Chem.
286:22262–74.
- de Laureto P.P., Tosatto L., Frare E., Marin O., Uversky V.N., Fontana A. (2006)
Conformational properties of the SDS-bound state of alpha-synuclein probed by limited
proteolysis: unexpected rigidity of the acidic C-terminal tail. Biochemistry 45:11523–31.
- de Rijk M. C., Launer L. J., Berger K., Breteler M. M., Dartigues J. F., Baldereschi M.,
Fratiglioni L., Lobo A., Martinez–Lage J., Trenkwalder C., Hofman A. (2000). Prevalence
of Parkinson's disease in Europe: A collaborative study of population–based cohorts
Neurologic Diseases in the Elderly Research Group. Neurology 54S21−S23.
- 126 -
- Dev K. Hofele S. Barbieri V.L. Buchman H. van der Putten (2003) Part II: alphasynuclein
and its molecular pathophysiological role in neurodegenerative disease.
Neuropharmacology 45:14–44.
- Di Fonzo A., Rohe C. F., Ferreira J., Chien H. F., Vacca L., Stocchi F., Guedes L., Fabrizio
E., Manfredi M., Vanacore N., Goldwurm S.,Breedveld G., Sampaio C., Meco G.,
Barbosa E., Oostra B. A. & Bonifati V. (2005) A frequent LRRK2 gene mutation
associated with autosomal dominant Parkinson's disease. Lancet 365, 412–415.
- Ding T.T., Lee S.J., Rochet J.C., Lansbury P.T. Jr. (2002) Annular alpha–synuclein
protofibrils are produced when spherical protofibrils are incubated in solution or
bound to brain–derived membranes. Biochemistry 41:10209–10217.
- Dobson C.M. (2001) The structural basis of protein folding and its links with human
disease. Phil Trans R Soc Lond B 356:133–145.
- Duda J.E., Giasson B.I., Gur T.L., Montine T.J., Robertson D., Biaggioni I., Hurtig H. I.,
Stern M.B., Gollomp S.M., Grossman M., Lee V.M.Y., Trojanowski J.Q. (2000)
Immunohistochemical and biochemical studies demonstrate a distinc profile of alpha–
synclein permutations in multiple system atrophy. J Neuropathol Exp Neurol 59:830–
841.
- Dunnett SB, Björklund A. (1999) Prospects for new restorative and neuroprotective
treatments in Parkinson's disease. Nature 399:A32–9.
- Ebeling W., Hennrich N., Klockow M., Metz H., Orth H.D., Lang H. (1974) Proteinase K
from Tritirachium album Limber. Eur J Biochem. 47):91-7.
- Esterbauer H., Schaur R.J., Zollner H., (1991) Chemistry and biochemistry of 4–
hydroxynonenal, malonaldehyde and related aldehydes. Free Radic. Biol. Med. 11:81–
128.
- Farooqui A.A., Horrocks L.A. (2006) Phospholipase A2-generated lipid mediators in the
brain: the good, the bad, and the ugly. Neuroscientist 12:245–260.
- Farrer M., Kachergus J., Forno L., Lincoln S., Wang D. S., Hulihan M., Maraganore D.,
Gwinn–Hardy K., Wszolek Z., Dickson D., Langston J. W. (2004) Comparison of kindreds
with parkinsonism and alpha–synuclein genomic multiplications. Ann. Neurol,
55:174−179.
- Fauvet B., Mbefo M.K., Fares M.B., Desobry C., Michael S., Ardah M.T., Tsika E., Coune
P., Prudent M., Lion N., Eliezer D., Moore D.J., Schneider B., Aebischer P., El-Agnaf
O.M., Masliah E., Lashuel H.A., (2012) α-Synuclein in central nervous system and from
erythrocytes, mammalian cells, and Escherichia coli exists predominantly as disordered
monomer. J. Biol. Chem. 287:15345–64.
- Fink A.L. (2006) The aggregation and fibrillation of alpha–synuclein. Acc. Chem. Res.
39:628–634.
- Fontana A., de Laureto P.P., Spolaore B., Frare E., Picotti P., Zambonin M. (2004)
Probing protein structure by limited proteolysis. Acta Biochim Pol. 51:299–321.
- Fredenburg R. A., Rospigliosi C., Meray R. K., Kessler J. C., Lashuel H. A., Eliezer D. &
Lansbury P. T. Jr (2007) The impact of the E46K mutation on the properties of alpha–
synuclein in its monomeric and oligomeric states. Biochemistry 46, 7107–7118.
- Fuchs J., Nilsson C., Kachergus J., Munz M., Larsson E.M., Schüle B., Langston J.W.,
Middleton F.A., Ross O.A., Hulihan M., Gasser T., Farrer M.J. (2007) Phenotypic
variation in a large Swedish pedigree due to SNCA duplication and triplication.
Neurology 68:916-22.
- 127 -
- Fujiwara H., Hasegawa M., Dohmae N., Kawashima A., Masliah E., Goldberg M.S., Shen
J., Takio K., Iwatsubo T., (2002) alpha–Synuclein is phosphorylated in synucleinopathy
lesions. Nat. Cell Biol. 4:160–164
- Galter D., Westerlund M., Carmine A., Lindqvist E., Sydow O., Olson (2006) LRRK2
expression linked to dopamine–innervated areas. Ann Neurol. 59714–9.
- Giasson B.I., Van Deerlin V.M. (2008) Mutations in LRRK2 as a cause of Parkinson's
disease. Neurosignals. 1699–105.
- Giasson B.I., Covy J.P., Bonini N.M., Hurtig H.I., Farrer M.J., Trojanowski J.Q., Van
Deerlin V.M. (2006) Biochemical and pathological characterization of Lrrk2. Ann Neurol.
Feb;59(2):315–22.
- Ghosh D., Mondal M., Mohite GM., Singh PK., Ranjan P., Anoop A., Ghosh S., Jha NN.,
Kumar A., Maji SK. (2013) the Parkinson's Disease–Associated H50Q Mutation
Accelerates α–Synuclein Aggregation in Vitro. Biochemistry 52:6925–7.
- Goers J., Manning–Bog A.B., McCormack A.L., Millett I.S., Doniach S., Di Monte D.A.,
Uversky V.N. & Fink A.L. (2003) Nuclear localization of alpha–synuclein and its
interaction with histones. Biochemistry 42:8465–8471.
- Golovko M.Y., Rosenberger T.A., Faergeman N.J., Feddersen S., Cole N.B., Pribill I.,
Berger J., Nussbaum R.L., Murphy E.J., (2006) Acyl–CoA synthetase activity links wild–
type but not mutant alpha–synuclein to brain arachidonate metabolism. Biochemistry,
45:6956–6966.
- Golovko M.Y., Rosenberger T.A., Feddersen S., Faergeman N.J., Murphy E.J. (2007)
Alpha–synuclein gene ablation increases docosahexaenoic acid incorporation and
turnover in brain phospholipids. J Neurochem 101:201–211.
- Golovko M.Y., Barcelo–Coblijn G., Castagnet P.I., Austin S., Combs C.K., Murphy E.J.
(2009) The role of alpha–synuclein in brain lipid metabolism: a downstream impact on
brain inflammatory response. Mol Cell Biochem, 326:55–66.
- Greenbaum E. A., Graves C. L., Mishizen–Eberz A. J., Lupoli M. A., Lynar D. R., Englander
S. W., Axelsen P. H. & Giasson G. I. (2005) The E46K mutantion in alpha–synuclein
increases amyloid fibril formation. J Biol Chem. 280:7800–7807.
- Greggio E., Lewis P.A., van der Brug M.P., Ahmad R., Kaganovich A., Ding J., Beilina A.,
Baker A.K. & Cookson M.R. (2007) Mutations in LRRK2/dardarin associated with
Parkinson disease are more toxic than equivalent mutations in the homologous kinase
LRRK1. J Neurochem 102:93–102.
- Gloeckner C.J., Kinkl N., Schumacher A., Braun R.J., O'Neill E., Meitinger T., Kolch W.,
Prokisch H., Ueffing M. (2006) The Parkinson disease causing LRRK2 mutation I2020T is
associated with increased kinase activity. Hum Mol Genet. 15:223–32.
- Haque F., Pandey AP, Cambrea LR, Rochet JC, Hovis JS. (2010) Adsorption of alpha–
synuclein on lipid bilayers: modulating the structure and stability of protein assemblies.
J Phys Chem B. 114:4070–81.
- Harper J.D., Wong S.S., Lieber C.M., Lansbury P.T. (1997) Observation of metastable
Abeta amyloid protofibrils by atomic force microscopy. Chem Biol. 4:119–125.
- Hamilton B. A. (2004) α–Synuclein A53T substitution associated with Parkinson disease
also marks the divergence of old word and new world primates. Genomics 83:739–742.
- Hardy J. (2010) Genetic analysis of pathways to Parkinson disease. Neuron. 68:201–
206.
- Hasegawa K, Kowa H. (1997) Autosomal dominant familial Parkinson disease: older
onset of age, and good response to levodopa therapy. Eur Neurol. 38:39–43.
- 128 -
- Herrera F.E., Chesi A., Paleologou K.E., Schmid A., Munoz A., Vendruscolo M.,
Gustincich S., Lashuel H.A., Carloni P., (2008) Inhibition of alpha–synuclein fibrillization
by dopamine is mediated by interactions with five C–terminal residues and with E83 in
the NAC region. PLoS One 3:e3394.
- Higashi S., Iseki E., Yamamoto R., Minegishi M., Hino H., Fujisawa K., Togo T., Katsuse
O., Uchikado H., Furukawa Y., Kosaka K., Arai H. (2007) Concurrence of TDP–43, tau and
alpha–synuclein pathology in brains of Alzheimer's disease and dementia with Lewy
bodies. Brain Res. 1184:284–94.
- Higashi S., Biskup S., West A.B., Trinkaus D., Dawson V.L., Faull R.L., Waldvogel H.J., Arai
H., Dawson T.M., Moore D.J., Emson P.C. (2007) Localization of Parkinson's disease–
associated LRRK2 in normal and pathological human brain. Brain Res. 2007 Jun
25;1155:208–19.
- Hokenson M.J., Uversky V.N., Goers J., Yamin G., Munishkina L.A., Fink A.L., (2004)
Role of individual methionines in the fibrillation of methionine–oxidized
alphasynuclein. Biochemistry 43:4621–4633.
- Hoyer W., Cherny D., Subramaniam V., Jovin T.M. (2004) Impact of the acidic C–
terminal region comprising amino acids 109–140 on alpha–synuclein aggregation in
vitro. Biochemistry 43:16233–42.
- Hoyer W., Cherny D., Subramaniam V., Jovin T.M. (2004) Rapid self–assembly of alpha–
synuclein observed by in situ atomic force microscopy. J Mol Biol. 340:127–39.
- Hornykiewicz O. (2002) L–DOPA: from a biologically inactive amino acid to a successful
therapeutic agent. Amino Acids. 23:65−70.
- Irvine G. B., El–Agnaf O. M., Shankar G. M., Walsh D. M. (2008) Protein aggregation in
the brain: the molecular basis for Alzheimer's and Parkinson's diseases. Mol. Med.
14:451−464.
- Jao, B.G. Hegde, J. Chen, I.S. Haworth, R. Langen (2008) Structure of membrane–bound
alpha–synuclein from site–directed spin labeling and computational refinement. Proc.
Natl. Acad. Sci. U. S. A. 105:19666–19671
- Jenner P. (1989) Clues to the mechanism underlying dopamine cell death in Parkinson's
disease. J Neurol Neurosurg Psychiatry Suppl:22–8.
- Jenner P. (2003).Oxidative stress in Parkinson’s disease. Ann. Neurol. 53:S26–S38.
- Jensen P. H., Nielsen M. S., Jakes R., Dotti C. G. & Goedert M. (1998) Binding of alpha–
synuclein to brain vesicles is abolished by familial Parkinson’s disease mutation. J Biol
Chem. 273:26292–4.
- Jo E., McLaurin J., Yip C. M., St George–Hyslop P. & Fraser P. E. (2000) alpha–Synuclein
membrane interaction and lipid specificity. J Biol Chem. 275:34328–34334.
- Kachergus J., Mata IF., Hulihan M., Taylor J.P., Lincoln S., Aasly J., Gibson J.M., Ross
O.A., Lynch T., Wiley J., Payami H., Nutt J., Maraganore D.M., Czyzewski K, Styczynska
M., Wszolek Z.K., Farrer M.J., Toft M. (2005) Identification of a novel LRRK2 mutation
linked to autosomal dominant parkinsonism: evidence of a common founder across
European populations. Am J Hum Genet. 76:672–80.
- Kang J.H., Kim K.S. (2003) Enhanced oligomerization of the alpha–synuclein mutant by
the Cu,Zn–superoxide dismutase and hydrogen peroxide system. Mol Cells. 15:87–93.
- Karyagina I, Becker S, Giller K, Riedel D, Jovin TM, Griesinger C, Bennati M. (2011)
Electron paramagnetic resonance spectroscopy measures the distance between the
external β–strands of folded α–synuclein in amyloid fibrils. Biophys J. 101:L1–3.
- 129 -
- Kiely AP, Asi YT, Kara E, Limousin P, Ling H, Lewis P, Proukakis C, Quinn N, Lees AJ,
Hardy J, Revesz T, Houlden H, Holton JL. (2013) α-Synucleinopathy associated with
G51D SNCA mutation: a link between Parkinson's disease and multiple system atrophy?
Acta Neuropathol. 125:753–69.
- Klivenyi, P., Siwek, D., Gardian, G., Yang, L., Starkov, A., Cleren, C., Ferrante, R. J.,
Kowall, N. W., Abeliovich, A., Beal, M. F. (2006) Mice lacking alpha–synuclein are
resistant to mitochondrial toxins. Neurobiol. Dis. 21:541−548.
- Koo H.C., Park Y.H., Lee B.C., Chae C., O'Rourke K.I., Baszler T.V. (2001)
Immunohistochemical detection of Prion protein (PrP-Sc) and epidemiological study of
BSE in Korea. J Vet Sci. 2:25–31.
- Kösel S., Przuntek H., Epplen J.T., Schöls L., Riess O. (1998) Ala30Pro mutation in the
gene encoding alpha–synuclein in Parkinson's disease. Nat Genet. 18:106–8.
- Kruger R., Kuhn W., Müller T., Woitalla D., Graeber M., Kösel S., Przuntek H., Epplen
J.T., Schöls L., Riess O. (1998)et al. Ala30Pro mutation in the gene encoding -synuclein
in Parkinson's disease. Nature Genet. 18:106−108.
- Kumar K.R., Lohmann K., Klein C. (2012) Genetics of Parkinson disease and other
movement disorders. Curr. Opin. Neurol. 25:466–474.
- Khurana R., Ionescu–Zanetti C., Pope M., Li J., Nielson L., Ramírez–Alvarado M., Regan
L., Fink A.L., Carter S.A. (2003) A general model for amyloid fibril assembly based on
morphological studies using atomic force microscopy. Biophys J. 85:1135–44.
- Lai H.J., Lin C.H., Wu R.M. (2012) Early–onset autosomal–recessive parkinsonian–
pyramidal syndrome. Acta Neurol Taiwan. 21:99–107.
- Langston JW, Ballard P, Tetrud JW, Irwin I. (1983) Chronic Parkinsonism in humans due
to a product of meperidine–analog synthesis. Science 219:979–80.
- Langston J.W. (1985) MPTP neurotoxicity: an overview and characterization of phases
of toxicity. Life Sci. 36:201−206.
- Lashuel H.A., Petre B.M., Wall J., Simon M., Nowak R.J., Walz T., Lansbury P.T. Jr. (2002)
Alpha–synuclein, especially the Parkinson's disease–associated mutants, forms pore–
like annular and tubular protofibrils. J Mol Biol. 322:1089–102.
- Lashuel H.A., Hartley D., Petre B.M., Walz T., Lansbury P.T. Jr. (2002)
Neurodegenerative disease: amyloid pores from pathogenic mutations. Nature
418:291.
- Lashuel H.A., Overk C.R., Oueslati A., Masliah E. (2013) The many faces of α–synuclein:
from structure and toxicity to therapeutic target. Nat Rev Neurosci 14:38–48.
- Lee C., Choi C., Lee S.J., (2002) Membrane–bound alpha–synuclein has a high
aggregation propensity and the ability to seed the aggregation of the cytosolic form. J.
Biol. Chem. 277:671–678.
- Lees, A. J. (2009). The Parkinson chimera. Neurology 72:S2–S11.
- Lees, A. J., Hardy, J., Revesz, T. (2009). Parkinson’s disease. Lancet 373:2055–2066.
- Lewy, F. H. (1923). Die Lehre vom Tonus und der Bewegung: zugleich systematische
Untersuchungen zur Klinik, Physiologie, Pathologie und Pathogenese der Paralysis
agitans. Julius Springer Verlag.
- Lesage S, Brice A. (2009) Parkinson's disease: from monogenic forms to genetic
susceptibility factors. Hum Mol Genet. 18:48–59.
- Lewitt P.A. (2008) Levodopa for the treatment of Parkinson's disease. N. Engl. J. Med.
359:2468−2476.
- 130 -
- Li X., Tan Y.C., Poulose S., Olanow C.W., Huang X.Y., Yue Z. (2007) Leucine–rich repeat
kinase 2 (LRRK2)/PARK8 possesses GTPase activity that is altered in familial Parkinson's
disease R1441C/G mutants. J Neurochem. 103:238–47.
- Lim S.Y., Lang A.E. (2010) The nonmotor symptoms of Parkinson's disease––an
overview. Mov Disord. 25:S123–30.
- Lokappa S.B., Ulmer T.S., (2011) α–Synuclein populates both elongated and brokenhelix
states on small unilamellar vesicle. J. Biol. Chem. 286:21450–2145.
- Lukiw W.J., Bazan N.G. (2008) Docosahexaenoic acid and the aging brain. J Nutr.
138:2510–2514.
- Madine, Doig A.J., Middleton D.A., (2006) A study of the regional effects of alpha–
synuclein on the organization and stability of phospholipid bilayers. Biochemistry
45:5783–5792.
- Maekawa T., Kubo M., Yokoyama I., Ohta E., Obata F. (2010) Age–dependent and cell–
population–restricted LRRK2 expression in normal mouse spleen. Biochem Biophys Res
Commun. 392:431–5.
- Mazzuca C., Orioni B., Coletta M., Formaggio F., Toniolo C., Maulucci G., De Spirito M.,
Pispisa B., Venanzi M., Stella L. (2010) Fluctuations and the rate-limiting step of
peptide-induced membrane leakage. Biophys J. 99:1791−800.
- McLaurin J., Yip C.M., StGeorge–Hyslop P., Fraser P.E., (2000) alpha–Synuclein
membrane interactions and lipid specificity. J. Biol. Chem. 275:34328–34334.
- Murphy RM. (2007) Kinetics of amyloid formation and membrane interaction with
amyloidogenic proteins. Biochim Biophys Acta 1768:1923–34.
- Mata I.F., Wedemeyer W.J., Farree M.J., Taylor J.P., Gallo K.A. (2006). LRRK2 in
Parkinsoni’s disease: protein domains and functional insights. TRENDS in Neuroscience
29:286–293.
- McLean P.J., Kawamata H., Ribich S., Hyman B.T., (2000) Membrane association and
protein conformation of alpha–synuclein in intact neurons. Effect of
Parkinson'sdisease–linked mutations, J. Biol. Chem. 275:8812–8816.
- Melrose H.L., Lincoln S.J., Tyndall G., Dickson D., Farrer M. (2006) Anatomical
localization of leucine–rich repeat kinase 2 in mouse brain. Neuroscience 139:791–4.
- Melrose H.L., Kent C.B., Taylor J..P, Dachsel J..C, Hinkle K.M., Lincoln S.J., Mok S.S.,
Culvenor J.G., Masters C.L., Tyndall G.M., Bass D.I., Ahmed Z., Andorfer C.A., Ross O.A.,
Wszolek Z.K., Delldonne A., Dickson D.W., Farrer M.J. (2007) A comparative analysis of
leucine–rich repeat kinase 2 (Lrrk2) expression in mouse brain and Lewy body disease.
Neuroscience 147:1047–58.
- Miake H., Mizusawa H., Iwatsubo T., Hasegawa M. (2002) Biochemical characterization
of the core structure of alpha–synuclein filaments. J Biol Chem. 277:19213–9.
- Nasstrom T., Wahlberg T., Karlsson M., Nikolajeff F., Lannfelt L., Ingelsson M.,
Bergstrom J., (2009) The lipid peroxidation metabolite 4–oxo–2–nonenal cross–links
alpha–synuclein causing rapid formation of stable oligomers. Biochem. Biophys. Res.
Commun. 378:872–876.
- Nasstrom T., Fagerqvist T., Barbu M., Karlsson M., Nikolajeff F., Kasrayan A., Ekberg M.,
Lannfelt L., Ingelsson M., Bergstrom J. (2011) The lipid peroxidation products 4–oxo–2–
nonenal and 4–hydroxy–2–nonenal promote the formation of alphasynuclein
oligomers with distinct biochemical, morphological, and functional properties. Free
Radic. Biol. Med. 50:428–437.
- 131 -
- Lee H.J., Choi C., Lee S.J. (2002) Membrane–bound alpha–synuclein has a high
aggregation propensity and the ability to seed the aggregation of the cytosolic form. J
Biol Chem. 277:671–8.
- Necula M., Chirita C.N., Kuret J., (2003) Rapid anionic micelle–mediated alpha–
synuclein fibrillization in vitro. J. Biol. Chem. 278:46674–46680.
- Nonaka T., Iwatsubo T., Hasegawa M., (2005) Ubiquitination of alpha–synuclein.
Biochemistry 44:361–368.
- Norris E.H., Giasson B.I., Ischiropoulos H., Lee V.M., (2003) Effects of oxidative and
nitrative challenges on alpha–synuclein fibrillogenesis involve distinct mechanisms of
protein modifications. J. Biol. Chem. 278:27230–27240.
- Okochi M., Walter J., Koyama A., Nakajo S., Baba M., Iwatsubo T., Meijer L., Kahle P.J.,
Haass C., (2000) Constitutive phosphorylation of the Parkinson's disease associated
alpha–synuclein. J. Biol. Chem. 275:390–397.
- Ozansoy M, Başak AN. (2013) The central theme of Parkinson's disease: α–synuclein.
Mol Neurobiol. 47:460–5.
- Paleček E., Ostatná V., Masarík M., Bertoncini C.W., Jovin T.M. (2008) Changes in
interfacial properties of alpha–synuclein preceding its aggregation. Analyst. 133:76–84.
- Paleologou K.E., Oueslati A., Shakked G., Rospigliosi C.C., Kim H.Y., Lamberto G.R.,
Fernandez C.O., Schmid A., Chegini F., Gai W.P., Chiappe D., Moniatte M., Schneider
B.L., Aebischer P., Eliezer D., Zweckstetter M., Masliah E., Lashuel H.A. (2010)
Phosphorylation at S87 is enhanced in synucleinopathies, inhibits alphasynuclein
oligomerization, and influences synuclein–membrane interactions. J. Neurosci.
30:3184–3198.
- Papapetropoulos, S., Paschalis, C., Athanassiadou, A., Papadimitriou, A., Ellul, J.,
Polymeropoulos, M., Papapetropoulos, T. (2001) Clinical phenotype in patients with α–
synuclein Parkinson’s disease living in Greece in comparison with patients with
sporadic Parkinson’s disease. J. Neurol. Neurosurg. Psychiatry 70:662–665.
- Paisan–Ruiz C., Jain S., Evans E. W., Gilks W. P., Simon J., van der Brug M., Lopez de
Munain A., Aparicio S., Gil A. M., Khan N., Johnson J., Martinez J. R., Nicholl D., Carrera
I. M., Pena A. S., de Silva R., Lees A., Marti–Masso J. F., Perez–Tur J., Wood N. W. &
Singleton A. B. (2004) Cloning of the gene containing mutations that cause PARK8–
linked Parkinson's disease. Neuron 44:595–600.
- Perrin R.J., Woods W.S., Clayton D.F. & George J.M. (2000) Interaction of human alpha–
synuclein and Parkinson’s disease variants with phospholipids. Structural analysis using
site– directed mutagenesis. J Biol Chem. 275:34393–34398.
- Perrin R.J., Woods W.S., Clayton D.F., George J.M., (2001) Exposure to long chain
polyunsaturated fatty acids triggers rapid multimerization of synucleins. J. Biol. Chem.
276:41958–41962.
- Polymeropoulos M. H., Lavedan C., Leroy E., Ide S. E., Dehejia A., Dutra A., Pike B., Root
H., Rubenstein J., Boyer R., Stenroos E. S., Chandrasekharappa S., Athanassiadou A.,
Papapetropoulos T., Johnson W. G., Lazzarini A. M., Duvoisin R. C., Di Iorio G., Golbe L.
I., Nussbaum R. L. (1997) Mutation in the alpha–synuclein gene identified in families
with Parkinson's disease. Science 276:2045–2047.
- Proukakis C., Dudzik C.G., Brier T., MacKay D.S., Cooper J.M., Millhauser G.L., Houlden
H., Schapira A.H. (2013) A novel aS missense mutation in Parkinson disease. Neurology
801062–4.
- 132 -
- Przedborski S., Vila M. (2001) The last decade in Parkinson's disease research. Basic
sciences. Adv Neurol 86:177–86.
- Qin Z., Hu D., Han S., Reaney S.H., Di Monte D.A., Fink A.L., (2007) Effect of 4–hydroxy–
2– nonenal modification on alpha–synuclein aggregation. J. Biol. Chem. 282:5862–
5870.
- Quilty M.C., King A.E., Gai W.P., Pountney D.L., West A.K., Vickers J.C. (2006), Alpha-
synuclein is upregulated in neurones in response to chronic oxidative stress and is
associated with neuroprotection. Exp Neurol, 199 pp. 249–256.
- Quin Z., Hu D., Han S., Hong D. P., Fink A. L. (2007) Role of different regions of α–
synuclein in assembly of fibrils. Biochemistry 46:13322–30.
- Ramsay R.R., Salach J.I., Dadgar J., Singer T.P. (1986) Inhibition of mitochondrial NADH
dehydrogenase by pyridine derivatives and its possible relation to experimental and
idiopathic parkinsonism. Biochem. Biophys. Res. Commun. 135:269–75.
- Ramakrishnan M., Jensen P.H., Marsh D. (2003) Alpha–synuclein association with
phosphatidylglycerol probed by lipid spin labels. Biochemistry 42:12919−12926.
- Reale M., Pesce M., Priyadarshini M., Kamal M.A., Patruno A. (2012) Mitochondria as
an easy target to oxidative stress events in Parkinson's disease. CNS Neurol Disord Drug
Targets 11430–8.
- Rhoades E., Ramlall T.F., Webb W.W., Eliezer D. (2006) Quantification of alpha–
synuclein binding to lipid vesicles using fluorescence correlation spectroscopy. Biophys
J. 90:4692–4770.
- Rott E., Szargel R., Haskin J., Shani V., Shainskaya A., Manov I., Liani E., Avraham E.,
Engelender S. (2008) Monoubiquitylation of alpha–synuclein by seven in absentia
homolog (SIAH) promotes its aggregation in dopaminergic cells, J. Biol. Chem.
283:3316–3328.
- Ruipérez V, Darios F, Davletov B. (2010) Alpha–synuclein, lipids and Parkinson's
disease. Prog Lipid Res. 49:420–8.
- Sampathu D.M., Giasson B.I., Pawlyk A.C., Trojanowski J.Q., Lee V.M. (2003)
Ubiquitination of alpha–synuclein is not required for formation of pathological
inclusions in alpha–synucleinopathies. Am. J. Pathol. 163:91–100
- Sandal M., Valle F., Tessari I., Mammi S., Bergantino E., Musiani F., Brucale M., Bubacco
L., Samorì B (2008) Conformational equilibria in monomeric alpha–synuclein at the
single– molecule level. PLoS Biol. 6:e6.
- Sciacca M.F., Brender J.R., Lee D.K., Ramamoorthy A. (2012) Phosphatidylethanolamine
enhances amyloid fiber-dependent membrane fragmentation. Biochemistry 51:7676-
84.
- Scott D., Roy S. (2012) α–Synuclein inhibits intersynaptic vesicle mobility and maintains
recycling–pool homeostasis. J Neurosci. 32:10129–10135.
- Serpell L.C. (2000) Alzheimer's amyloid fibrils: structure and assembly. Biochim Biophys
Acta 1502:16–30.
- Sharon R., Bar–Joseph I., Frosch M.P., Walsh D.M., Hamilton J.A., Selkoe D.J. (2003) The
formation of highly soluble oligomers of alpha–synuclein is regulated by fatty acids and
enhanced in Parkinson's disease. Neuron 37:583–595.
- Sharon R., Bar–Joseph I., Frosch M.P., Walsh D.M., Hamilton J.A., Selkoe D.J., (2003)
The formation of highly soluble oligomers of alpha–synuclein is regulated by fatty acids
and enhanced in Parkinson's disease. Neuron 37:583–595.
- Shults C. W. (2006) Lewy bodies. Proc. Natl. Acad. Sci. U S A 103:1661−1668.
- 133 -
- Singleton A. B., Farrer M., Johnson J., Singleton A., Hague S., Kachergus J., Hulihan M.,
Peuralinna T., Dutra A., Nussbaum R., Lincoln S., Crawley A., Hanson M., Maraganore
D., Adler C., Cookson M. R., Muenter M., Baptista M., Miller D., Blancato J., Hardy J.,
Gwinn–Hardy K. (2003) alpha–Synuclein locus triplication causes Parkinson's disease.
Science 302:841.
- Singleton A., Gwinn–Hardy K., Sharabi Y., Li S.T., Holmes C., Dendi R., Hardy J.,
Singleton A., Crawley A., Goldstein D. S. (2004) Association between cardiac
denervation and parkinsonism caused by alpha–synuclein gene triplication. Brain
127:768–772.
- Singleton A.B., Farrer M.J., Bonifati V. (2013) The genetics of Parkinson's disease:
progress and therapeutic implications. Mov Disord. 28:14–23.
- Smith W.W., Margolis R.L., Li X., Troncoso J.C., Lee M.K., Dawson V.L., Dawson T.M.,
Iwatsubo T., Ross C.A., (2005) Alpha–synuclein phosphorylation enhances eosinophilic
cytoplasmic inclusion formation in SH–SY5Y cells. J. Neurosci. 25:5544–5552.
- Spillantini M. G., Crowther R. A., Jakes R., Hasegawa M. ,Goedert M. (1998) alpha–
Synuclein in filamentous inclusions of Lewy bodies from Parkinson's disease and
dementia with Lewy bodies. Proc. Natl. Acad. Sci. U S A, 95:6469–6473.
- Taymans J.M., Van den Haute C., Baekelandt V. (2006) Distribution of PINK1 and LRRK2
in rat and mouse brain. J Neurochem. 98:951–61.
- Thakur P., Nehru B. (2013) Long-term heat shock proteins (HSPs) induction by
carbenoxolone improves hallmark features of Parkinson's disease in a rotenone-based
model. Neuropharmacology. 79:190–200.
- Thomas B., and Beal M.F. (2007) Parkinson's disease. Hum. Mol. Genet. 16:183–193.
- Tolleson C.M., Fang J.Y. (2013) Advances in the mechanisms of Parkinson's disease.
Discov Med. 15:61–6.
- Tosatto L., Andrighetti A.O., Plotegher N., Antonini V., Tessari I., Ricci L., Bubacco L.,
Dalla Serra M. (2012) Alpha-synuclein pore forming activity upon membrane
association. Biochim Biophys Acta 1818:2876–2883.
- Turnbull S., Tabner B.J., El–Agnaf O.M., Moore S., Davies Y., Allsop D. (2001) alpha–
Synuclein implicated in Parkinson’s disease catalyses the formation of hydrogen
peroxide in vitro. Free Radic. Biol. Med. 30:1163–70.
- Uchida K. (2003) Histidine and lysine as targets of oxidative modification. Amino Acids.
25:249–57.
- Ulmer T.S. & Bax A. (2005) Comparison of structure and dynamics of micelle–bound
human alpha–synuclein and Parkinson disease variants. J Biol Chem. 280:43179–43187.
- Uversky V.N., Li J., Fink A.L. (2001) Metal–triggered structural transformations,
aggregation, and fibrillation of human α–synuclein. J Biol Chem. 276:44284–96.
- Uversky V.N., Li J., Fink A.L. (2001b) Evidence for a partially folded intermediate in α–
synuclein fibril formation. J Biol Chem. 276:10737–44.
- Uversky V.N., Yamin G., Munishkina L.A., Karymov M.A., Millett I.S., Doniach S.,
Lyubchenko Y.L., Fink A.L. (2005). Effects of nitration on the structure and aggregation
of alpha–synuclein. Brain Res. Mol. Brain Res. 134:84−102.
- Van Den Eeden S.K., Tanner C.M., Bernstein A.L., Fross R.D., Leimpeter A., Bloch D.A.,
Nelson L.M. (2003) Incidence of Parkinson's disease: variation by age, gender, and
race/ethnicity. Am J Epidemiol. 157:1015–22.
- Venda L.L., Cragg S.J., Buchman V.L., Wade–Martins R. (2010) α–Synuclein and
dopamine at the crossroads of Parkinson's disease. Trends Neurosci. 33:559–68.
- 134 -
- Vilar M., Chou H.T., Luehrs T., Maji S. K., Riek–Loher D., Vere R., Manning G., Stahlberg
H., Riek R. (2008). The fold of α–synuclein fibrils. Proc. Natl. Acad. Sci. USA 105:8637–
42.
- Vilarino–Guell C., Wider C., Ross O.A., (2011) VPS35 mutations in Parkinson disease.
Am J Hum Genet. 89:162–7.
- Volles M. J. & Lansbury P. T. Jr (2002) Vesicle permeabilization by protofibrillar alpha–
synuclein is sensitive to Parkinson’s disease–linked mutations and occurs by a pore–like
mechanism. Biochemistry 41:4595–4602.
- Yoritaka A., Hattori N., Uchida K., Tanaka M., Stadtman E. R., Mizuno Y. (1996)
Immunohistochemical detection of 4–hydroxynonenal protein adducts in Parkinson
disease. Proc. Natl. Acad. Sci. USA 93:2696–2701.
- Wakabayashi K., Engelender S., Yoshimoto M., Tsuji S., Ross C. A. & Takahashi H. (2000)
Synphilin–1 is present in Lewy bodies in Parkinson’s disease. Ann Neurol 47:521–523.
- Wang A., Costello S., Cockburn M., Zhang X., Bronstein J., Ritz B (2011) Parkinson's
disease risk from ambient exposure to pesticides. European Journal of Epidemiology
26:547–555.
- West A.B., Moore D.J., Biskup S., Bugayenko A., Smith W.W., Ross C.A., Dawson V.L.,
Dawson T.M. (2005) Parkinson's disease–associated mutations in leucine–rich repeat
kinase 2 augment kinase activity. Proc. Natl. Acad. Sci. U S A 102:16842–16847.
- Westerlund M, Hoffer B, Olson L. (2010) Parkinson's disease: Exit toxins, enter genetics.
Prog Neurobiol. 90:146–56.
- Wood S.J., Wypych J., Steavenson S., Louis J.C., Citron M., Biere A.L. (1999) α–Synuclein
fibrillogenesis is nucleation dependent. J Biol Chem. 278:19509–19512.
- Wood–Kaczmar A., Gandhi S., Wood N. W. (2006) Understanding the molecular causes
of Parkinson's disease. Trends Mol Med. 12:521–528.
- Zakharov S.D., Hulleman J.D., Dutseva E.A., Antonenko Y.N., Rochet J.C. & Cramer W.A.
(2007) Helical alpha–synuclein forms highly conductive ion channels. Biochemistry
46:14369–14379.
- Zarranz J. J., Alegre J., Gómez–Esteban J. C., Lezcano E., Ros R., Ampuero I., Vidal L.,
Hoenicka J., Rodriguez O., Atarés B., Llorens V., Gomez Tortosa E., del Ser T., Muñoz D.
G., de Yebenes J.G. (2004). The new mutation, E46K, of alpha–synuclein causes
Parkinson and Lewy body dementia. Ann. Neurol. 55:164–173.
- Zhu, Li J., Fink A.L., (2003) The association of alpha–synuclein with membranes affects
bilayer structure, stability, and fibril formation. J. Biol. Chem. 278:40186–40197
- Zhu, Fink A.L., (2003) Lipid binding inhibits alpha–synuclein fibril formation. J.
Biol.Chem. 278:16873–16877.
- Zhu M., Qin Z.J., Hu D., Munishkina L.A., Fink A.L., (2006) Alpha–synuclein can function
as an antioxidant preventing oxidation of unsaturated lipid in vesicles. Biochemistry
45:8135–8142.
- Zimprich A., Biskup S., Leitner P., Lichtner P., Farrer M., Lincoln S., Kachergus J., Hulihan
M., Uitti R. J., Calne D. B., Stoessl A. J., Pfeiffer R. F., Patenge N., Carbajal I. C., Vieregge
P., Asmus F., Muller–Myhsok B., Dickson D. W., Meitinger T., Strom T. M., Wszolek Z. K.
& Gasser T. (2004) Mutations in LRRK2 cause autosomal–dominant parkinsonism with
pleomorphic pathology. Neuron 44:601–607.
- Zimprich A., Benet–Pagès A., Struhal W., Graf E., Eck S.H., Offman M.N., Haubenberger
D., Spielberger S., Schulte E.C., Lichtner P., Rossle S.C., Klopp N., Wolf E., Seppi K.,Pirker
W., Presslauer S., Mollenhauer B., Katzenschlager R., Foki T., Hotzy C., Reinthaler E.,
- 135 -
Harutyunyan A., Kralovics R., Peters A., Zimprich F., Brücke T., Poewe W., Auff E.,
Trenkwalder C., Rost B., Ransmayr G., Winkelmann J., Meitinger T., Strom T.M. (2011) A
mutation in VPS35, encoding a subunit of the retromer complex, causes late–onset
Parkinson disease. Am J Hum Genet. 89:168–175.
- 136 -